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RUBBER EXTRUSION PARAMETER
OPTIMIZATION
Pauliina Peltola
Final Thesis
February 2013
Paper- , Textile- and
Chemical Engineering
Chemical Engineering
TIIVISTELMÄ
Tampereen ammattikorkeakoulu
Paperi-, tekstiili- ja kemiantekniikka
Kemiantekniikka
PAULIINA PELTOLA:
Kumin suulakepuristuksen parametrien optimointi
Opinnäytetyö 138 sivua, joista liitteitä 1 sivu
Helmikuu 2013
Opinnäytetyön tilannut yritys tarjoaa erilaisia lastinkäsittelylaitteita ja -ratkaisuja
asiakkailleen. Opinnäytetyö tehtiin yrityksen merenkulkuun ja erityisesti kuivarahtiin
erikoistuneeseen yksikköön, jonka yksi tuoteryhmä on alihankintana valmistetut
lastiluukuntiivisteet rahtilaivoihin. Opinnäytetyössä haettiin optimaalisia ajoparametreja
uuden lineaarisen lastiluukuntiivistetuotteen suulakepuristusta varten. Työssä
tarkasteltiin ruuvinopeutta, kumimassan lämpötilaa ja ulostulevan profiilin
pintalämpötilaa. Kyseiset ajoparametrit ovat vain tälle yhdelle tietyn muodon ja koon
omaavalle tiivisteelle kun se valmistetaan yhdellä tietyllä kumisekoitusreseptillä,
suulakkeella ja kylmäsyöttö suulakepuristimella. Yrityksen lopullinen tavoite on saada
tämä lineaarinen tiivistetuote hallittuun massatuotantoon. Tämän opinnäytetyön
teoriaosa käsittelee kumia materiaalina ja sisältää lyhyen yleiskatsauksen kumituotteen
suunnitteluun, valmistukseen, eri työstötekniikkoihin ja kumin testaukseen. Näitä
aiheita on käsitelty lastiluukun kumitiivistetuotannon näkökulmasta ja tätä
opinnäytetyötä tullaan käyttämään uusien suunnittelijoiden perehdytysmateriaalina.
Optimaalisten ajoparametrien löytämiseksi suoritettiin nykyisen työohjeen ohjearvojen
perusteella niistä alitettuja ja ylitettyjä koeajoja 13 kappaletta. Tiedot koeajoista
kerättiin manuaalisesti ja niitä käsiteltiin Excel -taulukkolaskentaohjelmalla.
Suulakepuristimen koeajoparametrien arviointi perustui niiden tuottamien tulosten
vertailuun tuotteen teknisessä piirustuksessa olevien mittatoleranssien ja
standardipuristumakäyrän välillä.
Saatujen tulosten perusteella nykyisen työohjeen ruuvinopeus, kumisekoituksen paine ja
lämpötila voivat kaikki olla hieman nykyistä korkeampia. Kaikista kriittisimmäksi
ajoparametriksi tämän tuotteen osalta muodostui kumisekoituksen lämpötila
suulakepuristimen päässä. Ylärajoja ei saavutettu ajoparametrien kanssa, mutta
alarajoista saatiin enemmän tietoa. Yksi tuotteen teknisen piirustuksen apumitoista
kannattaisi myös lisätä kriittisiin mittoihin antamalla sille mittatoleranssiraja. Tässä
työssä tehtyjen laajojen ajoparametriyhdistelmien jälkeen on helpompi tarkastella
jotakin tiettyä parametria ja sen vaikutusta tiivistetuotannon laatuun tarkemmin. On
suositeltavaa toistaa työssä löydetyt ajoparametrit kolmesti pitkien ajoaikojen kanssa,
jotta voidaan lopullisesti varmistua opinnäytetyön tuloksista.
Asiasanat: ekstruusio, kumi, kumitiiviste, lastiluukku, suulakepuristus.
ABSTRACT
Tampereen ammattikorkeakoulu
Tampere University of Applied Sciences
Paper-, Textile- and Chemical Engineering
Chemical Engineering
PAULIINA PELTOLA:
Rubber Extrusion Parameter Optimization
Bachelor's thesis 138 pages, appendices 1 page
February 2013
The company which ordered this final thesis is providing a wide range of cargo
handling equipment and solutions. This final thesis was carried out for the marine
division and especially to the department which designs dry cargo related solutions.
This thesis is a study for the optimal parameters for cold-feed rubber extrusion with one
new hatch cover packing profile for bulk vessels. Optimal parameters are for this
specific profile shape and size with one specific compound recipe, die and extruder.
Final aim for the company is to get this linear profile into controlled mass production.
This final thesis is going to be used as training material for new designers. The theory
deals with rubber as a material and it consists of short general review into rubber
product manufacturing. Designing of rubber product is reviewed as well as different
machining and test methods, from the point of view of hatch cover packing.
Experimental extrusions were carried out with parameters above and below from the
present working instructions for this seal product. Data from these totally 13 different
combination of experimental extrusion parameters, were collected manually. From each
extrusion 3 duplicate samples were taken. From them, dimensions before and after
vulcanization, hardness, surface quality and compression curves were studied. The data
was processed with Excel spreadsheet. The results were referred to the dimension
tolerances and standard compression curve of the technical drawing for this packing
product.
These results suggest that the current ranges of present working instruction can be
updated into higher values, what comes to the screw speed, head compound pressure
and temperature. The head compound temperature was found to be the most critical one
from these three parameters under study. In the technical drawing of this packing
product, one dimension tolerance can be changed from additional to critical one by
giving it a tolerance. Further research is required to confirm these now founded
extrusion parameters by conducting extrusion according to the new extrusion parameter
ranges three times with longer extrusion times.
Key words: extrusion, hatch cover, packing, rubber, seal.
4
INDEX
1 INTRODUCTION ....................................................................................................... 6
2 RUBBER AND RUBBER PACKINGS ..................................................................... 8
2.1 Short review into the history of rubber ................................................................ 8
2.2 Rubber as a material ............................................................................................ 9
2.2.1 Rubber types and rubber grades .............................................................. 12
3 RUBBER PRODUCT MANUFACTURING ........................................................... 18
3.1 Rubber product designing .................................................................................. 18
3.1.1 Hatch cover packing designing ............................................................... 19
3.2 Rubber compounding ......................................................................................... 21
3.3 Machining methods ............................................................................................ 25
3.4 Vulcanization ..................................................................................................... 27
3.4.1 Vulcanization methods ............................................................................ 29
3.5 Finishing ............................................................................................................ 31
3.6 Recycling ........................................................................................................... 31
4 EXTRUSION ............................................................................................................ 33
4.1 Extrusion theory ................................................................................................. 34
4.2 Extrusion set-up ................................................................................................. 35
4.3 Extrusion head ................................................................................................... 38
4.4 Extrusion dies .................................................................................................... 41
4.4.1 Die shaping ............................................................................................. 44
4.5 Challenges in extrusion ...................................................................................... 46
5 RUBBER TESTING ................................................................................................. 49
5.1 Testing before vulcanization .............................................................................. 49
5.1.1 Rheology ................................................................................................. 50
5.2 Testing after the vulcanization ........................................................................... 51
5.2.1 Hardness .................................................................................................. 52
5.2.2 Tensile stress ........................................................................................... 53
5.2.3 Compression ............................................................................................ 53
5.2.4 Tear ......................................................................................................... 55
5.2.5 Creep, relaxation and set ......................................................................... 55
5.2.6 Friction and wear..................................................................................... 56
5.2.7 Fatigue ..................................................................................................... 57
5.2.8 Effect of temperature............................................................................... 58
5.2.9 Fire-resistance ......................................................................................... 60
5.2.10 Ozone ...................................................................................................... 60
5.2.11 Environmental resistance ........................................................................ 61
5
6 CARGOSHIPS AND HATCH COVER PACKING ................................................ 64
6.1 Cargo ship types ................................................................................................. 64
6.1.1 Bulk carriers ............................................................................................ 65
6.2 Hatch covers and hatch cover packing............................................................... 67
6.2.1 Side-rolling hatch covers and the new packing product ......................... 69
6.3 Operating conditions and demands for the hatch cover packing ....................... 72
6.3.1 The future of hatch cover packing .......................................................... 75
7 CONFIDENTAL ....................................................................................................... 76
8 CONFIDENTAL ....................................................................................................... 77
9 CONFIDENTAL ....................................................................................................... 78
10 CONFIDENTAL ....................................................................................................... 79
11 CONFIDENTAL ....................................................................................................... 80
REFERENCES ................................................................................................................ 81
ATTACHEMENTS ........................................................................................................ 84
Attachement 1. Confidental ....................................................................................... 84
6
1 INTRODUCTION
This final thesis is studying one rubber product machining technique extrusion from the
point of view what is relevant in the present hatch cover packing manufacturing of the
company. This study is concentrating only into a one specific linear hatch cover packing
product while hatch cover packing corners are made with molding technique. This
linear seal profile is manufactured with cold-feed extruder which has one feed-screw.
The parameters to be optimized are the screw speed of extruder, the extrusion head
compound temperature and the surface temperature of output seal profile.
This final thesis is based on to the present extrusion parameters of the working
instruction. There was no specific parameter or direction to be taken, only confirm that
the present parameters are the best ones. To gain this information there were conducted
experimental extrusions above and below these present values. Totally 13 different
combinations of extrusion parameters were extruded and three duplicate samples were
taken from each combination. Three duplicate samples were taken from all of the
extrudates, starting from band-end closest to the extruder, at intervals of 70 cm. Before
and after vulcanization four different dimensions were measured from these totally 39
duplicate samples. Hardness was measured on Shore A –scale from every duplicate
sample. Compression curves were measured, while sample was in metal holder, which
imitates the rubber channel, where the packing is located in hatch cover. Finally the
detail dimensions of profiles were measured. Dimensions after vulcanization and
compression curves were compared with the actual extrusion parameters to find the
relations between them.
Major part of products which are designed in the dry cargo has something to do with
metals and especially steel. Rubber materials are minority part of the designing, but
crucial part of the weathertight hatch cover. It is important for designers also have basic
knowledge of rubber material besides of metals. This final thesis theory is reweaving
essential parts of rubber product manufacturing. In the experimental part of this final
thesis which is confidential, there is dealt the present hatch cover packing
manufacturing in more details. Rubber as a material is very different when compared it
to other materials. In this final thesis theory there are several examples of its
uniqueness. When one wants to use wood material choice can be made between
7
different trees like pine or mahjong. In some cases used wood material can also be
combinations of few different trees. When one wants to use rubber material choice can
also be made between different rubbers like natural rubber or chloroprene rubber but
there are not available just a chloroprene rubber but several different chloroprene
rubbers with different chemical compositions. In chapter 3.2 is told more about rubber
compounding and choices one has to make when using this material.
8
2 RUBBER AND RUBBER PACKINGS
Rubbers and plastics are consisting of short molecule chain units called monomers.
When these units are linked to each other polymer is formed. In polymer there are
certain frequencies for one or more monomers to be appearing in it. Polymer is a rubber
when its main chain is flexible in the temperature it is used, its individual chains can be
cross-linked to each other and its main chains has not got any weak links (example O-
O) (Kothandaraman 2008, 1–2). This cross-linking of rubber is achieved by
vulcanization (see chapter 3.4) which plastics do not need.
2.1 Short review into the history of rubber
In 1521 was the first written word about the rubber balls although first rubber plants are
known to exist from over 50 million years. These balls were made of natural rubber
latex of the Hevea brasieliensis rubber trees, caoutchouc. No-one knows when the latex
of rubber plant was found useful the first time. Rubber plants only grow in the area
which is inside of 15 degrees, on both ways, from the equator. Europeans were very
suspicious about the new magical material but some of them used it in order to help
different diseases. (Palo-oja & Willberg 1998, 17–72.)
Synthetic rubber was created after hard demands of rubber raw material which could not
be satisfied in the end of the 1800 –century because Brazil owned 80 % of the worlds
rubber raw material resources. Demanding only increased after the air filled rubber tire
was invented and the motorization spread fast. At the beginning of the 1900 -century the
pressure just kept arising to find another source of rubber raw material beside of the
natural rubber. The first one, who patented the synthetic rubber manufacturing method,
was a German chemist Fritz Hofmann in 1909. During the wars rubber was one of the
most important raw materials for the war equipments and every country tried to be self-
supported. Natural rubber again came to be more used than synthetic rubber because
synthetic rubbers did not have any better features or the costs were too high to achieve
those. (Palo-oja & Willberg 1998, 17–72.)
9
Wars had a big effect to the rubber industry. In 1933 styrene-butadiene rubber (SBR)
was invented by the Germans, ethane-propene rubber (EPM) and ethane-propene-diene
rubber (EPDM) was invented by the Italian industry during the years 1958 – 1959. In
the early 1980’s 70 % of the natural rubber production was in Southeast Asia and only 1
% in Brazil. (Palo-oja & Willberg 1998, 17–72.)
Rubber first came to Finland in the middle of the 1800 –century as goloshes which were
luxury products. Rubber parts were also imported inside of different industrial
machinery which were bought from foreign countries. Even then, the rubber recipes
were highly classified which meant that rubber product workshop establishing was
almost impossible in Finland. The first goloshes made in Finland were so poor-quality
that it took a long time to convince customers that those Finnish rubber products had as
good quality as the imported ones. In 1915 Finnish rubber manufacturer, called Suomen
Gummitehdas Osakeyhtiö, had already a wide rubber product range from a golosh to a
rubber packing beside of the different kinds of tires and hoses. Another one like that
general rubber product plant was not established, on the contrary, workshops were
created to specialize into only narrow range of rubber products. (Palo-oja & Willberg
1998, 17–72.)
In the middle of 1920’s, due to the lack of natural rubber, Finnish rubber industry begun
the usage of secondary rubber raw material. During the wartime the usage of reclaim
increased temporarily. Recycling is not developed because of the environmental
concerns during the latest years on the contrary it was taken into usage because of the
lack of virgin rubber raw material. During the 1960’s slowly increasing building and
automotive industry the demand for different kind of rubber profile bands encouraged
Finnish technical rubber producer to expand their production into rubber profile bands,
too. (Palo-oja & Willberg 1998, 17–72.)
2.2 Rubber as a material
The main feature that distinguishes rubber from other materials is its reversible
deformation ability (even 1000 %). Rubber has a unique mix of features: small
toughness, it is almost perfectly incompressible, it has good wear-resistance, high
friction and good resistance to corrosion. Due to these features, rubber has functions
10
like elasticity, damping, sealing, protection and / or holding together. Toughness is
depended from the number of cross-linking sections in rubber material. The rubber will
be tougher if number of those sections increases. (Nokia tekninen kumi N.D. 23; Mark
& Others 2005, 402, 405.)
The production distribution between natural and synthetic rubber in the world is seen in
figure 1 (adapted from International Rubber Study Group 2012, modified). In figure 2
(adapted from Mark, Erman & Eirich 2005, 402, modified) is shown in more details
which industries uses the natural rubber.
FIGURE 1. World Rubber Production in 2011 (adapted from International Rubber
Study Group 2012, modified)
11
FIGURE 2. Global Natural Rubber Consumption (adapted from Mark & Others 2005,
402, modified)
Rubber is a unique material also in its ageing features, with ageing is meant chemical
process caused by oxygen in the air, which results into a loss in physical features.
Rubber has a memory meaning that the conditions and events it has undergone during
its lifecycle can withstand in it. There are big effects on the quality of rubber in the way
it has been stored; has it been in a warehouse where the temperature arises close to +40
°C during summer time, or has it been in very moisture air or has the raw rubber been
frozen during the storing. (Metalliteollisuuden Keskusliitto, MET 2001, 153; Väliaho
2012.)
Rubber does not have such a positive image from the environmental point of view
because synthetic rubber is made from crude oil the same way as plastics are. The usage
of plastics is in larger volumes than the usage of rubbers. This is the reason why plastics
re-usage is generally more studied which also has led to that it is partly easier to carry
out. As seen in the figure 3 (adapted from Mark, J. & Others 2005, 404–405, modified),
the biggest consumer of the synthetic rubbers is the tire industry which uses about 60 %
of the global synthetic rubber. (Nokia tekninen kumi N.D. 23; Mark & Others 2005,
402, 405.)
12
FIGURE 3. Global Synthetic Rubber Consumption (adapted from Mark & Others 2005,
404–405, modified)
2.2.1 Rubber types and rubber grades
There exist several different types of synthetic rubber besides natural rubber. Both,
natural and synthetic, rubbers are divided further to different grades with several
different ways. For example, natural rubber is available in three basic grades:
technically specified, visually inspected rubber and specialty rubbers. There are six
basic types of technically specified natural rubber: L, CV, 5, 10, 20, and 50. These
grades have specific features, example, in dirt and ash content and with Mooney
viscosity. Same thing is with the synthetic rubbers they are divided further into different
grades and the characteristics of those grades can have dramatic differences between
each other. This leads into a situation where purchasing of raw-materials have to be
extremely professional and accurate.
60 %
10 % 9 % 6 % 5 % 4 % 3 % 2 % 1 %
13
As an example of the simplicity of the term ‘rubber’ here are presented the following
review into one rubber and its grades. One of the synthetic rubbers is polyethylene diene
rubber (EPDM). When purchasing EPDM one has to choose from a wide range of
different kinds of EPDMs. This elastomer has different kinds of features depending on
the diene, for example, ethyliedene norbornene (ENB) is ten times more expensive than
dicyclo pentadiene (DCPD). DCPD is cheap but its methine hydrogen may affect the
cure efficiency. On the other hand 1, 4 hexadiene (HD) has the best ozone and heat
resistance and it also gives ease for recycling the EPDM. EPDM usually has 4 – 5 %
content of diene which can be increased to 8 – 10 % if faster cure is needed. Ethylene
content in EPDM can vary from 45 to 75 % and when it increases it betters the
extrusion with lower die swell and better shape retention but impairs the ease of mixing.
(Mark & Others 2005, 402–405; Kothandaraman 2008, 54.)
Table 1 is presenting the main features of natural rubber and few common synthetic
rubbers. There are also figures of the monomer for most of the elastomers in table 1.
Operating temperature range for each elastomer varies a lot between different literature
sources, these temperature ranges in the table 1 are the most careful ones.
14
TABLE 1. Few Rubber Types (Nokia tekninen kumi N. D. 11, 36, 48–49, 51; Dick
2004, 239; Mark & Others 2005, 404; Kothandaraman 2008, 11, 35, 42, 44, 49–51, 53,
55, 57, 59, 62, 143; Lipasti 2008, 15, 17, Attachement Kumityyppien ominaisuuksia –
table; Laurila 2011, 47, 53, 59, 61, 64–65, 67; figures: Pauliina Peltola 2012)
Elastomer Features and examples of
products
Long-term operating
temperature range
[°C]
NR Natural rubber
(cis-polyisoprene)
Nonpolar
High tensile and tear strength
without fillers
Fast cure rate due to the carbon
double bonds
Pure microstructure which
means content of cis-formed
molecule is 100 %
Excellent resilience
Good cold resistance
As a elastomer renewable
natural resource
Cannot withstand oils
Poor weather and ozone
resistance
Limited lifetime in high
temperatures and oxidative
environments
Products: tires, shoes, seals,
hoses
From -22 to 55
IR
Isoprene rubber
(cis-polyisoprene)
So-called fake natural
rubber
Features like NR
Microstructure consists of
different isoprene molecules
unlike NR
Does not get hard during storage
Poor residual compression
Poor weather and ozone
resistance
Cannot withstand oils
Quite expensive
Products: tires, shoes, seals,
hoses
From -55 to +70
SBR
Styrene-butadiene
rubber
(polystyrene/butadiene)
Nonpolar
Cheap
When styrene content arise
From -20 to +70
15
processability and tensile
strength will increase but on the
other hand temperature features
and resilience will decrease at
the same time (styrene content
23 – 25 % is the best)
Excellent resilience
Excellent residual compression
features
Resistance to acids
Good ageing resistance
Poor weather and ozone
resistance
Cannot withstand oils
Largest volume synthetic rubber
due to the tire industry
Products: hoses, conveyor belts
BR
Butadiene rubber
(polybutadiene)
Used only in rubber mixes
Fast cure rate due to the carbon
double bonds
Excellent resistant to freezing
Good resilience
Poor mechanical properties
Poor processability
Poor weather and ozone
resistance
Cannot withstand oils
Products: tires
From -70 to + 80
NBR
Nitrile rubber
(polyacrylonitrile-
butadiene)
Polar
Excellent residual compression
Resistant to hot water
Good resistance to oils
Reinforcing fillers is a must for
getting good strength properties
Poor ozone and weather
resistance
Products: oil refining related
products
From -10 to +70
CO,
ECO
Epichlorohydrin rubber
(polyethylene oxide,
polyepichlorohydrin)
Excellent weather and ozone
resistance
Good residual compression
Good resistance to oils
ECO is quite expensive
Products: oil refining related
products
From -10 to +80
ACM
Acrylic rubber
(polyacrylate)
Excellent weather and ozone
resistance
Good resistance to oils
Poor water and gas resistance
Poor resilience
Poor acid and base resistance
Products: motor seals and hoses
From -25 to +150
16
CR
Chloroprene rubber
(polychloroprene)
Polar
High tensile and tear strength
without fillers
Self-extinguishing (halogen
included)
Good weather and ozone
resistance
Better oil resistance than NR but
only to splash oil
Crystallization feature restricts
use at low temperatures
Quite expensive
Products: weatherproof seals,
conveyor and vee belts
From -20 to +70
EPM,
EPDM
(polyethylene-
propylene)
(polyethylene-propylene
diene)
(ethylidenenorbornene
trimer)
Nonpolar
Excellent electrical, heat, ozone,
weather and light resistance,
suitable for out-doors
Good chemical, wear and heat
resistance
Can be extended with large
amount of oils which leads to
lower costs, although elastomer
itself is not the cheapest one
Slow cure rate
Poor gas and oil resistance
Poor strength properties
Poor glue-ability and self-
adhesion
Products: seals (aviation,
highway joints, petroleum),
cable coverings, profile bands
From -30 to +80
CM,
CSM
Chlorinated ethylene
rubber
(chloro-polyethylene)
Chlorosulfonated
ethylene rubber
(chloro-sulfonyl-
polyethylene)
Excellent heat, ozone and
weather resistance
Good chemical resistance
CSM has excellent wear
resistance and color
preservability
Products: chemical hoses,
rubber blankets
From -20 to +80
IIR Butylrubber
(polybutyl)
Nonpolar
Excellent heat resistance
Excellent gas tightness
Good weather and ozone
resistance
Resistant to oxidative chemicals
Resistance to acids
Slow cure rate
Low resilience
Difficult to process
Cannot withstand oils
From -10 to +80
17
Poor resistance to freezing
Products: tire tubes, cables,
seals, steam hoses, balloons
Q Silicone rubber
(polysiloxane)
Excellent heat and cold
resistance
Good ozone resistance
Poor resistance to steam
Poor wear resistance
Cannot withstand oils
Poor resilience and gas tightness
Poor resistance to acids and
bases
Products: special seals, cable
covering
From -50 to +200
FPM Fluorine rubber
(polyheksafluorineprope
ne/ vinyldienefluoride)
Excellent heat and chemical
resistance
Excellent weather and ozone
resistance
Good oil and fat resistance
Good resistance to oils
Better acid than base resistance
Low resilience
Products: special oil resistant
seals and hoses for high
temperatures
From -20 to +175
The line between plastics and rubbers is getting more and more inaccurate in the future.
New materials are being developed and these two materials are mixed-up together.
Rubber and plastic are evolving towards polymer technology which includes elastomers
and polymers. (Nokia tekninen kumi N.D. 18.)
18
3 RUBBER PRODUCT MANUFACTURING
Basis for any rubber product are demands for performance, quality, environment and
cost. Performance demands come from the customer and the rubber product should
answer to these with good quality features, like durability and good appearance. Not
forgetting surety that the quality will be consistent and products will be uniform. More
and more environmental demands are affecting the manufacturing and end-use features,
including disposal. (Mark & Others 2005, 453.)
3.1 Rubber product designing
Rubber designing is considered to be more challenging than designing products from
other materials. Rubber compound is unpredictable and small changes in the rubber
compound will have effects which can be sometimes not logical, at first hand.
Designing rubber products is said to be ‘black-art’. Basis of the design work is
functional product, suitable lifetime and the possible additions, like fibers, structural
stiffeners or coatings. Elastomer is just a part of the rubber product but it should be
chosen correctly to answer to the chemical and physical demands of the products end-
use environment. Additives and fillers can only support the features of that elastomer.
(Nokia tekninen kumi N.D. 48, 52, 58; Metalliteollisuuden Keskusliitto, MET 2001,
129)
Mechanical product shape optimizing will increase the rubber products lifetime.
Processing possibilities will often cut down the design alternatives which seem good on
the paper. Better rubber designing aims to avoid local strain maximums in the rubber
product and tries to distribute the strain evenly throughout the product. Long-term
deformations should be small, no deformation over 30 %. The viscoelastic nature of
rubber and big deformations sets challenges into the designing stage. Rubber material
also undergo shrinkage during the machining approximately 1 – 4 %. (Nokia tekninen
kumi N.D. 48, 52, 58; Metalliteollisuuden Keskusliitto, MET 2001, 129)
The physical end-use environment of a product and synergism of chemical factors will
not either help the design work. Service life is also hard to evaluate because of the
19
features mentioned above. There are also installation and maintenance point of views to
be considered. In practice, designing rubber products are married to testing the best
early stage prototypes as finished products. This differs from other material designing
because with rubbers it is done already in early stage more by practical work than
theoretically. Rubber prototype products are tested in imitated working environment
using accelerated ageing in higher temperatures than the real working environment has.
Though, there are signs indicating that accelerated heat ageing tests will lead to
overestimating the natural ageing effects (Brown, Butler & Hawley 2001a, 21).
In packing designing there are features like lubricating film, pressure and pressure
shocks to be taken under consideration. Especially with rubber packing the effect of
substances are important to be tested: is there any swelling or shrinking of the rubber,
when it is in contact with them. The structural demands of packing design begin from
the profile shape and possible air channels that give more elasticity to the final product.
Thermal durability of the final packing product should also be tested to find out the
lowest and highest operating temperatures. (Nokia tekninen kumi N.D. 48, 52, 58;
Metalliteollisuuden Keskusliitto, MET 2001, 129.)
Usually the elastomer chosen for the product is compromise between the several wanted
features. For example, good oil resistance demands polar elastomers, which means the
molecule chains interactions are large-scaled and resistance to freezing is due to that,
poor. Another example is, when good strength properties are achieved with weak
polysulfic networking but this means that heat stability and residual compression will be
poor. (Nokia tekninen kumi N.D. 48, 52, 58; Metalliteollisuuden Keskusliitto, MET
2001, 129.)
3.1.1 Hatch cover packing designing
Hatch cover packing designing, same as every other rubber application, demands
comprehensive knowledge and approach from the designer, not only rubber knowledge
but more specific the demands of the end-use environment. Hatch cover seal is the final
piece of the complicated and wide jigsaw puzzle. This rubber product is a vital
component of the final product which is the weathertight hatch cover. Packing itself is a
20
volume product which means the cost-effectiveness is the base of design and it limits
the raw-material choices.
There are available designing equations for a few simple geometries when rubber pads
are in compression. None of these can cover fully the packing designing and finite
element analysis is the only usable tool in packing designing, because of these products
complex nature. By complex nature is meant the profile shape and end-use environment
of hatch cover packing with its several different forces and movements. Finite element
analysis is only a tool and the results still depends from the skills of the analyst, if he or
she can benefit from this accurate, versatile and comprehensive method. It can be very
roughly said that finite element analysis is based on meshing the rubber product. It is
dividing it into small parts which can be studied more carefully as independent units.
Böl & Reese (2005, 25) have created a finite element simulation for elastomeric
polymers, which is based on physical chain statistic. In this simulation the only user-
defined parameter is the ratio of the number of chains per reference volume. Simulation
already consists of number of chain segments, number of chains per reference volume
and the parameter which depends on the valance and the rotation angle of the chains.
This way local strains and stresses in the microstructure of a rubber product are found
and can be taken account in the design process. Figure 4 is showing an example of
rubber-boot meshed in finite element analysis (adapted from Böl & Reese 2005, 21–22).
21
FIGURE 4. Finite Element Analysis of Rubber-boot (adapted from Böl & Reese 2005,
21–22)
3.2 Rubber compounding
Compounding term means what to mix together while mixing term tells how to mix.
Rubber is always a forced mixed compound of different substances. The reason for this
complicated mix is that no elastomer can work alone because of the lack of vital
features demanded from rubber product. These features are not achieved only by the
elastomer usage alone. All of the materials in rubber compound have to be
environmental safe. This means meeting the current demands arising from the current
chemical effect knowledge. Compound should also meet the occupational health and
22
safety requirements, not to mention the processability in the manufacturing facilities
and cost effectiveness. (Nokia tekninen kumi N.D. 51; Johnson 2001, 9; Mark & Others
2005, 325, 401; Brown 2006, 65, 72, 76, 82–83, 104–105; Hahtola 2006, 25; Vuori
2006, 6, 13, 17; Kothandaraman 2008, 13, 140; Lipasti 2008, 18, 20; Murtoniemi 2010,
8–10; Laurila 2011, 39–44.)
In mastication natural rubber which has very long molecule chains, is compounded
alone. This way the longest chains are cut to shorter ones. Mastication helps the
following modification because the rubber gets softer. It requires the presence of
oxygen because oxygen binds the new created reactive chain ends and prevents them to
rejoining to each other again. Mastication helps to reduce the molecule weight of natural
rubber but it is not needed for synthetic rubbers. Their molecule weight is adjusted
already in the polymerization phase. (Nokia tekninen kumi N.D. 51; Johnson 2001, 9;
Mark & Others 2005, 325, 401; Brown 2006, 65, 72, 76, 82–83, 104–105; Hahtola
2006, 25; Vuori 2006, 6, 13, 17; Kothandaraman 2008, 13, 140; Lipasti 2008, 18, 20;
Murtoniemi 2010, 8–10; Laurila 2011, 39–44.)
Rubber compound is blend of different substances. It can be divided into elastomers,
filler systems, stabilizer systems, vulcanization system components and special
materials. There are also several other different classifications for the rubber compound
substances, depending from the point of view. Every substance added to the compound,
will have some effect to the processability no matter what is the real purpose of the
substance in question. Table 2 is presenting few interesting compound substances and
their features.
23
TABLE 2. Rubber Compound Components (Nokia tekninen kumi. N.D. 20; Gent 2001,
25, 28–29; Johnson 2001, 61–62, 64, 83; Mark & Others 2005, 368–369;
Kothandaraman 2008, 111, 118–119, 141–143; Lipasti 2008, 18–19)
Component Examples of substances Effect to the compound
Fillers Carbon blacks, clays, silicas, silicates,
calcium carbonate (CaCO3), magnesium
carbonate (MgCO3), talc
Small particle size and good
dispersion with the compound
reduce resilience, improve
tensile strength
Lowers prize
Carbon black add of 30 % can
increase the tensile strength
1000 %
Plasticizers Oils (aromatic oils, naphthenic oils,
paraffinic and chlorinated paraffinic oils)
Mineral oils (cheapest ones), liquid
polymers (the most expensive ones),
fatty acids, pine tar, rosin, esters, factice
Content generally around 25 %
When content arises plasticizers
are called extenders
Gives toughness, lowers prize,
improves resilience and
resistance to low temperatures
Reduces heat build-up during
mixing
Gives better flame-retardation
with halogenated plasticizers
Other additives Fibers, cross-linking agents, pigments,
oils, resins, perfumes, metal oxides
For adjusting toughness and
compound drying
For better smell and appearance
Can be a tackifying addition
Additives
Accelerators Sulfur Cross-linking and chain length
adjusting
Activators Metal oxides (like ZnO), fat acids
(stearic acid)
To activate vulcanization
systems accelerators
Retarders Magnesium oxide (MgO) for
halobutylrubber compounds
Delays the initiation of
vulcanization, reducing the
possibility of premature
vulcanization or scorch
Protective agents Antioxidants, antiozonants, protection
waxes
(aromatic amines, phenolics,
phosposites)
Thermal and UV resistance,
antioxidants, antiozonants (like
PVC into NBR)
These agents move to the
surface of product which can
lead to dyeing
Mixing agents Soap-like agents, chemical peptizers
(sulfonic acids and
pentachlorothiophenol)
Processing aids that lowers
viscosity
Coupling agents For silica filler Links between fillers and
elastomers, without decrease of
resilience
Reinforcement, improves
strength
Blowing agents Gas releasers and solvents Creates puffiness and cells
inside the matrix
24
Compound recipe is created in phr (per hundred rubber) units where every component
are counted in relation to hundred elastomer units. For example, recipe can start from
NR 90 phr and EPDM 10 phr with addition of carbon black 30 phr. This is why recipes
are always more than hundred units. In good quality compound the elastomer content is
around 50 – 60 % but more often in reality it is 35 – 40 % depending from the rubber
application and machining method. High elastomer content in compound is expensive
although the other substances are not either free of charge. Oil loads into the compound
reduce viscosity and mechanical properties. Extrudability is improved with reinforcing
fillers but heat generation is also increased during mixing. This may cause over mixing
and reduce mechanical features. Processability can be improved by adding liquid
rubbers in unsaturated rubbers, for example, liquid NR into NR compounds when it
becomes part of the cross-link net. This way mechanical properties are not reduced.
(Nokia tekninen kumi N.D. 51; Johnson 2001, 9; Mark & Others 2005, 325, 401; Brown
2006, 65, 72, 76, 82–83, 104–105; Hahtola 2006, 25; Vuori 2006, 6, 13, 17;
Kothandaraman 2008, 13, 140; Lipasti 2008, 18, 20; Murtoniemi 2010, 8–10; Laurila
2011, 39–44.)
Large scale compounding is done in mixing chambers where horizontally installed
rotors rotate to opposite directions. These chambers are huge three-store high
automatically controlled mixing units. Before these chambers, mixing was done with
mill rolls. Small volumes can still be mixed with these. Some smaller manufacturers can
still use mill rolls but it is more common for them to buy the compounding from a
bigger rubber company. (Nokia tekninen kumi N.D. 51; Johnson 2001, 9; Mark &
Others 2005, 325, 401; Brown 2006, 65, 72, 76, 82–83, 104–105; Hahtola 2006, 25;
Vuori 2006, 6, 13, 17; Kothandaraman 2008, 13, 140; Lipasti 2008, 18, 20; Murtoniemi
2010, 8–10; Laurila 2011, 39–44.)
Mixing the compound needs tack and adhesion to the mill roll or chamber. These
features can be increased by tackifying resins add. When fillers are added in high loads
there can be drying of the stock, this is why fillers should be added considerable. Steric
acid and waxes can fight against compound drying likewise prevent it to get stuck on to
the processing equipment. One of the most important phenomenons to avoid during all
the way mixing and machining is heat build-up. It can lead to thermal degradation,
unwanted vulcanization or even fire. The most critical point in rubber processing is
mixing which leads to problems later on if distributive or dispersive mixing is
25
incomplete. (Nokia tekninen kumi N.D. 51; Johnson 2001, 9; Mark & Others 2005, 325,
401; Brown 2006, 65, 72, 76, 82–83, 104–105; Hahtola 2006, 25; Vuori 2006, 6, 13, 17;
Kothandaraman 2008, 13, 140; Lipasti 2008, 18, 20; Murtoniemi 2010, 8–10; Laurila
2011, 39–44.)
Compound mixing process starts from feeding elastomer and other substances into a
mixer, in correct quantities, at right time and in specific order and in right temperatures.
The mixer is unloaded after actual mixing and this is followed by shaping and cooling
down the compound before the final step which is packing. Compounded rubber has
few unique features which are anomalous from other materials: high elasticity, abrasion
resistance and dampening properties. Compound storage before it has been machined
has effects to the compound. Viscosity increases during the storing until it reaches its
steady state. With natural rubber this is studied to take longer (600 hours) than with
synthetic rubbers (300 hours). Storing effects depends on the compound consistency, for
example, the viscosity change will be greater with high filler loads. (Nokia tekninen
kumi N.D. 51; Johnson 2001, 9; Mark & Others 2005, 325, 401; Brown 2006, 65, 72,
76, 82–83, 104–105; Hahtola 2006, 25; Vuori 2006, 6, 13, 17; Kothandaraman 2008,
13, 140; Lipasti 2008, 18, 20; Murtoniemi 2010, 8–10; Laurila 2011, 39–44.)
Basic commercial elastomers are available in thousands of different product names.
Choosing the right one is easy if there is computer database from the different elastomer
products and compound recipe features. When profile of the needed features is entered
into the database, it will provide the most suitable components and elastomers to the
user. This way the work is faster and more reliable, than choosing the best from
experience based knowledge or memory. (Nokia tekninen kumi N.D. 51; Johnson 2001,
9; Mark & Others 2005, 325, 401; Brown 2006, 65, 72, 76, 82–83, 104–105; Hahtola
2006, 25; Vuori 2006, 6, 13, 17; Kothandaraman 2008, 13, 140; Lipasti 2008, 18, 20;
Murtoniemi 2010, 8–10; Laurila 2011, 39–44.)
3.3 Machining methods
Rubber products can be machined several different ways. One of these methods,
extrusion, is treated more profound in chapter 4. Other machining methods are
calendaring, different mold techniques, coating and dipping.
26
Calendaring
With calendaring the product shape produced is rubber sheet. In calendaring machine
there are usually three to six cylinders and the product manufactured with it can be
sheet, film or reinforced sandwich structure, like conveyor belt. (Nokia tekninen kumi.
N.D. 41; Lipasti 2008, 22; Murtoniemi 2010, 15.)
Molding
Compression molded rubber products are the most common ones and this method is
also the most versatile processing method, it combines shaping and vulcanization
together. Transfer molding is a bit more advanced method compared to compression
molding. In this method compound is transferred from chamber threw channels to the
molds. Injection molding is the most advanced method compared to the other molding
methods. It combines extrusion screw-like part which warms-up and transfers the
rubber compound into a hot closed mold. This machining method suits the best for the
large quantity series. (Nokia tekninen kumi N.D. 41; Lipasti 2008, 22; Murtoniemi
2010, 15.)
Brushing / coating
In this method rubber paste is brushed onto fabric, after this solvent is evaporated and
rubber coated fabric can be vulcanized. One of the oldest products made with this
method are rain clothes likewise inflatable rubber boats are made this way. (Väliaho
1998b, 27.)
Dipping
A wide range of medical rubber products are manufactured by dipping, like gloves,
catheters and condoms. In this technique a product-specific tool is dipped first into
coagulation liquid and after that into latex liquid. After wanted layer is achieved, by
dipping the tool several times into the latex liquid, it is put into a heat oven where
drying and vulcanization happens. (Väliaho 1998b, 26.)
27
3.4 Vulcanization
Un-vulcanized rubber has the same features as chewing gum: it is sticky and do not
maintain its shape after a large deformation. Vulcanization is a vital process step in
rubber product manufacturing and will cause profound changes at the molecular level.
Vulcanization system consists of vulcanizate, accelerators, the activators for
accelerators and possible retarder. During the vulcanization elastomer chains are cross-
linked together resulting into molecular sized network (figure 5, adapted from Mark &
Others 2005, 322, modified). Cross-linking will happen in carbon double bond (C=C) or
in the pendant group of the elastomer.
FIGURE 5. Unculcanized Elastomer Chains and Vulcanized Network (adapted from
Mark & Others 2005, 322, modified)
Crosslink can be a single sulfur atom between the elastomer molecular chains (–R–S–
R–), an ionic cluster, a group of sulfur atoms in a short chain (–R–Sx–R–), a carbon to
carbon bond (–R–C–C–R– / –R–C=C–R–), a polyvalent organic radical or polyvalent
metal ion. Sulfur cure is the most common one used and it reacts with the unsatisfied
bonds in molecule chains. Sulfur curatives are the cheapest ones and give also the best
mechanical properties. Polysulfide cross links may also improve fatigue life. When
sulfur cure is used, if the sulfur content of partially soluble in rubber is more than 0.5 %
it reduces tack in built up. This high sulfur content causes also blooming on to the final
products surface spoiling the appearance. The usage of insoluble sulfur helps and it does
not reduce the scorch safety in compound storing. The risk of premature vulcanization
increases while compound is been stored. Blooming can be avoided by covering some
of the sulfur with sulfur donor substances. Another common cure is peroxide cure. It
28
gives good heat and set resistance. (Nokia tekninen kumi N.D. 42; Gent 2001, 23; Mark
& Others 2005, 321–324; Hahtola 2006, 25; Vuori 2006, 33; Kothandaraman 2008, 8,
94, 141–144; Murtoniemi 2010, 8–9; Laurila 2011, 32–33, 84–98.)
After the vulcanization rubber is relevantly insoluble into any solvent and cannot be
processed in any way which requires it to flow. Controllable vulcanization process is
vital in rubber product manufacturing if vulcanization starts too early the final form of
rubber article cannot be achieved. There is also the possibility of reversion if compound
is over-cured. This means crosslink loss due to the non-oxidative thermal aging. Most
severe reversions happen when temperature is above 155 °C and with the compounds
which contains many polysulfic crosslink. This leads to the usage of vulcanization delay
aids and scorch preventions. Still the wanted cross-linking should happen fast when
needed to and to be ended precisely at the right stage. Rubbers do not conduct well
thermally, which means the vulcanization time increases hand-in-hand when the product
size is getting larger. The vulcanization method, time and temperature should be
carefully chosen depending on the rubber product in question, to avoid the surface to be
over-cured and the inside to be uncured. (Nokia tekninen kumi N.D. 42; Gent 2001, 23;
Mark & Others 2005, 321–324; Hahtola 2006, 25; Vuori 2006, 33; Kothandaraman
2008, 8, 94, 141–144; Murtoniemi 2010, 8–9; Laurila 2011, 32–33, 84–98.)
Rubber is a viscoelastic liquid, no matter is it vulcanized or not. Solid rubber product
manufacturing necessitates elastomer chains to be linked chemically together by curing
agents. This leads to volume changes during the curing process because van der Waal
traction forces between elastomer molecule chains are replaced with shorter covalent
bonds. This phenomenon is demonstrated in figure 6 (adapted from Mark & Others
2005, 323, modified) where on the left side is seen un-vulcanized and on the right side
vulcanized rubber compound.
29
FIGURE 6. The Volume Change of Elastomer (adapted from Mark & Others 2005, 323,
modified)
3.4.1 Vulcanization methods
There are different methods to vulcanize rubber compound. The method may include,
for example, dry hot air, direct or indirect steam, microwaves, radiation or salt bath.
Vulcanization process can be continuous or batch working. In continuous method the
vulcanization happens straight after the machining. For example, after extrusion the
profile can go on conveyor belt through a vulcanization tunnel. Continuous
vulcanization demands special features from the compound like non-volatile and moist-
free additives. Batch working method means that machining and vulcanizations are
done in different stages. First the product is machined and stored up for a short period of
time when it has to wait access to a batch working vulcanization oven. Dimensional
stability is reached by connecting the elastomers, and other components of the
compound, together with the help of heat and chemicals. Simplest way to achieve this is
with the mold compression where during the machining the temperature of 150 – 200
°C will vulcanize the rubber compound. With calendar sheet products it is possible to
vulcanizate the sheet when it goes over a big hot cylinder after the machining. (Nokia
tekninen kumi N.D. 42; Gent 2001, 23; Mark & Others 2005, 321–324; Hahtola 2006,
25; Vuori 2006, 33; Kothandaraman 2008, 8, 94, 141–144; Murtoniemi 2010, 8–9;
Laurila 2011, 32–33, 84–98.)
One of the most common vulcanization methods for rubbers is steam vulcanization
which is done in autoclave. Autoclaves are also used in other places, like hospitals and
laboratories where they are used for sterilizing equipment. In autoclave hot high
30
pressured steam is surrounding the rubber products. Direct steam vulcanization leaves
the profile surface scaled that are called water prints. Generally used pressure varies
from 9 to 15 bars, while the temperature range is 180 – 200 °C. With extrusion it is
most common to have continuous vulcanization line which can be a hot air tunnel or salt
bath. Hot air vulcanization is recommended to extrudates with mass under 0.5 kg / m.
Salt bath contains generally 53 % potassium nitrate (KNO3), 40 % natrium nitrate
(NaNO3) and 7 % natrium nitrite (NaNO2). It suits for EPDM profiles which are
peroxide vulcanizates. After bath profile is washed and cooled down. (Nokia tekninen
kumi N.D. 42; Gent 2001, 23; Mark & Others 2005, 321–324; Hahtola 2006, 25; Vuori
2006, 33; Kothandaraman 2008, 8, 94, 141–144; Murtoniemi 2010, 8–9; Laurila 2011,
32–33, 84–98.)
With polar elastomers like NBR it is also possible to have microwave tunnel where
friction heats up the extrudate around 200 °C. Microwave tunnel is more economical
when the profile sizes are bigger. There are also available several other vulcanization
methods like infrared, fluidized method and radiation based. Fluidized method includes
small glass balls (diameter of 0.1 mm) in hot air temperature of 200 °C. Shock
vulcanization method with temperature of 600 °C is suitable for cellular rubber
products. (Nokia tekninen kumi N.D. 42; Gent 2001, 23; Mark & Others 2005, 321–
324; Hahtola 2006, 25; Vuori 2006, 33; Kothandaraman 2008, 8, 94, 141–144;
Murtoniemi 2010, 8–9; Laurila 2011, 32–33, 84–98.)
Vulcanization method and precise parameters are determined and based on the specific
compound features, only this way manufacturing is successful. Incompatible compound
cannot be cured successfully with any vulcanization. Compound, machining method
and vulcanization method are depended on each other. No features or deviations in
compound can be corrected in machining or vulcanization. (Nokia tekninen kumi N.D.
42; Gent 2001, 23; Mark & Others 2005, 321–324; Hahtola 2006, 25; Vuori 2006, 33;
Kothandaraman 2008, 8, 94, 141–144; Murtoniemi 2010, 8–9; Laurila 2011, 32–33, 84–
98.)
31
3.5 Finishing
Finishing can increase the manufacturing costs if complex finishing methods are
needed. After cooling down the vulcanized products they are checked if the surface
quality and dimensions are still according to the requirements. Finishing may include
one or more work steps like blast finishing when the rubber products are small-sized,
tearing, cutting with the large-sized products, grinding or punching. Cutting can be done
with water jet cutting or with laser which is quite expensive, though. (Väliaho 1998a,
50–51.)
3.6 Recycling
Rubber recycling is very complicated because vulcanization is irreversible process.
There are no good enough commercial method to recycle it. This is why the first
approach to recycling is minimizing the left-over volumes. The better are the production
planning, machining methods and process performance the less are the left-over
volumes. Vulcanized rubber is infusible thermoset material but un-vulcanized rubber
can be re-used quite easily even though it is processed. Reclaimed rubber means
depolymerisated vulcanized rubber where molecule chains are cut to smaller ones. More
profound method is devulcanization where the cross-link structure of rubber is
destroyed. This lateral method is more energy consuming and expensive. (Mark &
Others 2005, 663–665; Kothandaraman 2008, 123–125; Lipasti 2008, introduction, 13–
16.)
Reclaimed rubber is said to be a good improver for compound extrusion properties. It
gives better shape retention to the extrudate and also reduces die swell and shrinkage.
Un-vulcanized rubber can be mixed (only in small quantities) back into the virgin
rubber compound and then it can be processed again. Of course, the additives and
compound formula will restrict this. Some carefulness has to take while mixing because
rubber is unique material with its memory. Once processed rubber has some
minimalistic differences compared to the unprocessed rubber depending from the
current situation, compound and machining method. Extra compound rubber left over
from processing cannot be stored for a long time because compound will age quickly to
32
un-usable state. (Mark & Others 2005, 663–665; Kothandaraman 2008, 123–125;
Lipasti 2008, introduction, 13–16.)
Used old rubber products or new disqualified vulcanized articles are much harder to
recycle. Every different recycle method starts usually from the step where the rubber
waste is grinded. This grinded rubber can be used as cheapening additive up to 10 % in
new products but its usage is more and more restricted. Nowadays, rubber products
have got tight quality requirements and more demanding technical applications where
reclaimed rubber might have some negative effect. Grind can be used to non-critical
applications of rubber. It can also be used in landfill or in asphalt and cement modifying
but nowadays these too, are more restricted. One way to re-use tires is burning them
into energy but because of the risk of air pollution this is also currently more limited.
(Mark & Others 2005, 663–665; Kothandaraman 2008, 123–125; Lipasti 2008,
introduction, 13–16.)
Recycling methods can include retreating, reclaiming, pulverization, microwave and
ultrasonic processes, chemical treatment, pyrolysis or incineration. Microwave method
can be used when rubber has polar links, like sulfur. It is very energy-intensive. This is
due to the fact that rubber-waste is made into devulcanized rubber with breaking the
molecular level network formed in vulcanization. Although, after this rubber can be
added to a virgin rubber without any loss in mechanical properties. Ultrasonic method
only depolymerizes the rubber waste which means the rubbers re-usage properties are
poorer. Cost level between virgin raw-material and regenerate is more or less the same.
This means that manufacturers do not have any strong need for recycling as long as
virgin raw-material is cheaper and easier to use than the regenerate. Rubbers unique
material features leads to the situation where the creation of processed left-over rubber
or even just left-over compound is better to avoid in first place than recycle afterwards.
Tire industry has multiple rubber-waste volumes compared to other industries using
rubber. This is the reason why tire industry will presumably show the way and lead
other rubber industry branches to the possible new solutions in rubber recycling. (Mark
& Others 2005, 663–665; Kothandaraman 2008, 123–125; Lipasti 2008, introduction,
13–16.)
33
4 EXTRUSION
In this chapter extrusion is examined more detailed, unlike the other machining
methods. This chapter is concentrating into a cold-feed extruder with one screw and one
die. Studied linear packing of hatch cover is extrusion product, manufactured with cold-
feed extruder with one screw and one die.
In the late 19th
century Paul Troester and his business partners introduced the first screw
extruders to the rubber industry. Extruder is over one hundred year old technical
invention. First ones were cold-feed extruders that mean that rubber compound is in
room-temperature and extruder has to heat-up the compound itself. Later on, hot-feed
extruders were taken into usage. Hot-feed extruders had integrated heating units for the
compound. Nowadays, there are several differently structured extruders available, with
one or more screws, for example. Besides screw structured, there are also obtainable
ram extruders. Most commonly used ones are one die extruders although there are
available extruders with more dies. (Mark & Others 2005, 289; Lipasti 2008, 21;
Laurila 2011, 139–159.)
Extrusion technique is used mainly in hose and profile product manufacturing. There
are few prerequisites in extrusion like the correct compound behavior in die, which
includes dimension stability after the pressure and shape effect given by the die has
ended. Likewise rubber compound flow under steady pressure has to be achieved. In
figure 7 is shown the basic layout of the extruder type which is under study in this final
thesis. (Mark & Others 2005, 289; Lipasti 2008, 21; Laurila 2011, 139–159.)
34
FIGURE 7. Extruder Layout (figure: Pauliina Peltola 2012)
4.1 Extrusion theory
In this chapter are only dealt with the basics of extrusion theory. Extrusion principle is
simple but in practice extrusion is actually quite complicated and sensitive process.
Main parameters in extrusion are temperatures, head compound pressure and screw
speed. The dimensions of extrudate are measurable and the line speed of its reception
equipment is adjustable. They can also be considered as an extrusion parameters. Screw
speed is kept as a sensitive extrusion parameter, although it is compound related.
Compound pressure is not adjustable during extrusion same way as screw speed
because it depends from the viscosity of compound. Different extrusion parameters have
different time responses when they are changed during the extrusion and these are
depending on the parameter. For example, altering temperatures will effect slowly
because of the materials heat capacity, while altering the screw speed the effects are
immediate.
Flow in extruder is combination of transverse flow, drag flow, pressure flow and
leakage flow. In order to compound transfer inside the extruder friction between
compound and casing have to be greater, than friction between compound and screw.
This is why screw temperature is held higher than casing temperature. The better the
adhesion with rubber, the better the grip to barrel and the output will be greater.
Between cold metal and rubber there is no adhesion but as the temperature arises about
50 – 70 °C adhesion will appear. Above that temperature range grip again fades out
because rubber becomes softer. This is why feed zone is kept in that temperature range
35
mentioned, screw even higher and barrel cold. Figure 8 is showing a schematic diagram
of an extruder flow channel (adapted from Johnson 2001, 96). (Johnson 2001, 96–98,
106; Hahtola 2006, 40, 43–45; Laurila 2011, 145.)
FIGURE 8. Extruder Flow Channel (adapted from Johnson 2001, 96)
Rubber behaves like a viscous fluid all the way in screw channel and transverse
circulating flow happens in all cross-sections of the screw channel. The level of
circulations is studied depend upon back pressure. (Johnson 2001, 96–98, 106; Hahtola
2006, 40, 43–45; Laurila 2011, 145.)
4.2 Extrusion set-up
Feed
One important issue which affects to the result of the extrusion quality is feed and the
steadiness of feed (Väliaho 2012). First step in extrusion set-up is the rubber compound
feed which can be done by hand or by machinery. In the feed of extruders there is
cylinder which rotates to the opposite direction than the screw and this way transfers the
36
compound to the screw. The diameter size of feed cylinder is 1 – 2 times bigger than the
feed screw diameter. Fixed ratio roll drive cannot take variations of feed strip size. For
high precise extruding the feed strip has to be consistent width and thickness. Constant
rate of the feed is also vital, which means there should not be no flooding or starving in
feed hole. One interesting set-up in this step is the possibility of gear pump usage. These
pumps are more used in plastic extrusion but there are good results from applying them
into rubber extrusion. Rubber industry has been avoiding gear pumps because of their
sensitivity although they provide pressure and constant output of the melt. This helps
extruder to process more material when it is not used for pressure build-up anymore.
When gear pump is integrated into extruder it increases considerable the productivity
regardless of viscosity. (Aho 2008, abstract, 33–34.)
Screw
Gear and motor reduces the power to the screw which transfers the rubber compound
forward to the extrusion head. Extrusion screw geometry is complicated and it could be
said to be its own science. One basic feature of the screw is L / D relation which means
the screw length and diameter relation to each other. Commonly the L / D relation is
from 16 / D to 18 / D. These are longer screws for heating up the compound and the
relation means, for example, when the diameter of screw is 200 mm the length is 16
times bigger than the diameter, 3200 mm. Compound heating happens due to its friction
between the cylinder walls and screw. Screw mixes the rubber compound and it has
different zones in it: feed zone, compression and transfer zone, homogenous zone.
Another key figure in extruder is compression relation which means the volume change
of screw channels during the screw range. How much it gets smaller when moving
towards the extrusion head. Common compression relation is from 1: 1 to 1: 1.4
meaning the feed zone volume is 1.4 times larger than homogenous zone. Without
steady pressure behind the extrusion die the out-coming profile will not achieve the
right dimensions and shape. (Johnson 2001, 93–94, 106; Hahtola 2006, 22, 43; Vuori
2006, 25, 27; Laurila 2011, 139–144, 158.)
Casing
The casing of extruder is divided into different longitudinal areas which have their own,
separately adjustable water-circulation that is generally used to cooling down the
compound heated by friction. There should be enough output in water-circulation
pumps to be able to produce efficient thermal exchange. Compound temperature differs
37
from these casing areas because of rubbers poor thermal conductivity. Only small
surface area of the compound is in contact with the casing and they have only short
contact time due to the high-speed processing. Under lower processing speeds these
cooling areas have effect to the compound but when compound is pushed through the
extruder in high-speed there is no time to heat transfer to happen in real-time. When
compound temperature is higher, the mass expands and molecules are more separate
from each other which lead into easier slip of the molecules. When this optimum
temperature stage is been passed by, for example, with too high-speed extrusion, rubber
will finally be scorched. This means clusters of vulcanized rubber inside the profile and
/ or on the surface of it. In figure 9 (adapted from Laurila 2011, 158, modified) is shown
different aspects which are related to extrusion. These are not just the extruder machine
related matters. (Johnson 2001, 93–94, 106; Hahtola 2006, 22, 43; Vuori 2006, 25, 27;
Laurila 2011, 139–144, 158.)
FIGURE 9. The Aspects Related to Extrusion (adapted from Laurila 2011, 158,
modified)
38
4.3 Extrusion head
Extrusion head consist of screen, breaker plate and die, plus their holder cone in which
they are located. The functions of extrusion head is balancing the pressure across the
profile, guide rubber to the die and hold other items like sensors. In figure 10 is shown
demonstration of extrusion head, starting from left: screen, breaker plate, cone and die.
FIGURE 10. Extrusion Head Layout (figure: Pauliina Peltola 2013)
Inside the extrusion head compound has enough space to be used as container where
constant and steady flow is possible to the die, even though feed experiences some
changes. Volumetric flow does not change while it passes through the head but the
change in cross-sectional area leads to an increase of linear velocity as the rubber
undergoes elongational flow or stretching. This is why extrusion head should be long
enough to eliminate any pulsating flow. Pulsating flow can be formed because of non-
uniformity in compound viscosity level and homogeneity. Screen (see picture 1)
collects the clumps and wastes, although compound must be free of any clumps and
waste. If any they will quickly obstruct the screen and it has to be cleaned or replaced
interrupting the machining. Breaker plate (see picture 2) stops the compounds rotation
movement and works as a background plate for the screen. (Johnson 2001, 98, 108–109;
Hahtola 2006, 35, 41, 83; Vuori 2006, 29.)
39
PICTURE 1. Screen (picture: Pauliina Peltola 2012)
PICTURE 2. Breaker Plate (picture: Pauliina Peltola 2012)
With different hole sized breaker plates the resistance and friction based heat can be
affected. The smallest resistance is gained when large holed breaker plate is used
together with large profile sized die and no screen is used (see figure 11 right side).
Understandably, when a small hole sized breaker plate with fine screen and small sized
profile die is used the resistance is larger (see figure 11 left side).
40
FIGURE 11. Small Hole Size Die and Breaker Plate Compared with a Big Hole Size
Die and Breaker Plate (figure: Pauliina Peltola 2013)
The head pressure and the length of the fully filled screw zone are depending on the die
resistance and operating parameters. When screw becomes fully filled with rubber the
extruder is no longer a feed controlled. On the contrary, it operates in a metering mode.
Deviations in extrusion head pressure will cause poor homogeneity. One important
feature of the extrusion head its technical smartness related to the practical work while
processing. For example, automatic screen-changing devices and two hinge-mounted
heads or front head sections will ease the operating. These two lateral options give the
possibility of continuous extrusion while another one is used and the other one is under
normal extrusion maintenance. (Johnson 2001, 98, 108–109; Hahtola 2006, 35, 41, 83;
Vuori 2006, 29.)
The geometry of extrusion head channels effects to the rubbers swelling and shrinking.
The longer and wider the channels are, the more relaxed the rubber is. Extrusion head
cone should have optimized shape what comes to the rubber flow. If different sized
profiles are extruded there should also be available few add-one cones that can be used
to adjust the inside size of the cone. If the profile size is small compared to the inside
volume of extrusion head rubber compound dwell time will be long and it will lead to
different quality problems. Extrusion head should be as simple as possible to the rubber
flow, meaning there should not be any corners or loose spaces where compound can be
swirling around. Figure 12 is showing there are shown different inside volume sized
cones and rubber compound flows in them. As the figure 12 demonstrates the best
solution is the cone first from the right where the inside volume of cone is the smallest.
This leads to the situation where compound is most easily flowing through it to the die
and forward. (Johnson 2001, 98, 108–109; Hahtola 2006, 35, 41, 83; Vuori 2006, 29.)
41
FIGURE 12. Compound Flow in Extrusion Head (figure: Pauliina Peltola 2012)
4.4 Extrusion dies
Simplified die is the rubber profiles negative. This is not the whole truth because with
die shaping one has to take under consideration several different phenomenon, like the
die swelling. Extrusion die is the most demanding and complex part of the extrusion
process and success requires a lot of special professional experience from the workers
and die-makers. Rubber material has unique characteristic due to its viscoelastic nature
and special ingredients likewise their combination of effects in the compound. In
equation 1 (adapted from Johnson 2001, 98) is presented the volumetric output through
the die that equals the quantity conveyed by screw, minus the backflow down the screw
and the leakage flow. (Johnson 2001, 107–108, 111–112.)
(1)
Leakage flow is a result of the wearing of screw ridges and casing. The situation in
wearing should be kept under observation of operators. Transverse flow is vital in heat
transfer and distributive mixing. It also gives better physical and thermal homogeneity
of compound when it reaches the die. When compound viscosity is decreased it will
reduce the extrusion output because pressure flow and leakage flow are increased. On
the other hand, increase in viscosity will reduce the compound homogeneity because
leakage flow is decreased and this leads to poorer miscibility. (Johnson 2001, 107–108,
111–112.)
The operating conditions of extruder depend from the screw and die features. If these
are put to a graph of volumetric output and head pressure the operating point of this
specific screw and die combinations can be found from the intersection of the curves. In
42
figure 13 is presented a simplified extruder operation diagram of four different screw
and die combinations (adapted from Johnson 2001, 107).
FIGURE 13. Extruder Operation Diagram (adapted from Johnson 2001, 107)
In figure 13 is seen that back pressure has more effect on deeper channel screw than
shallow one. High back pressure also creates greater back flow with deeper channel
screw and small die than with the large die resulting into a better output with the lateral
one. This situation described in figure 13 is up-to-date only as long as screen pack is
clean. (Johnson 2001, 107–108, 111–112.)
When a simple pipe shape is extruded, the die output Q depends only from pressure and
viscosity while the fixed terms of die dimensions stays the same. In equation 2 is
presented die flow Q and how it depends from die length L, pressure P, viscosity η and
the radius R of die openings (adapted from Laurila 2011, 148).
(2)
Die shape is unique for that one specific extruder and most often, for that one elastomer
compound recipe. Extrusion process, including extrusion parameters and die shape,
43
should be so robust that no small variations in compound should have effect on it. When
the same extrusion product is done from two totally different compound recipes the
difference in their coefficient of thermal expansion leads to a different shrinking
magnitude and to the need of different die shaping. The coefficient of thermal expansion
for rubber varies from 50 – 200 ∙10-6
/ K. By using a cold die the smallest delicate profile
geometry is deformed because the rubber gets stuck into the cold die and do not flow
smoothly through it. (Johnson 2001, 107–108, 111–112; Metalliteollisuuden
Keskusliitto, MET 2001, 156; Mark & Others 2005, 291; Hahtola 2006, 21, 36;
Kothandaraman 2008, 14; Laurila 2011, 148–150.)
Die swelling happens when residual stresses accumulated by elastomer in extrusion are
released. Die swelling will increase when molecular weight and viscosity are decreased.
Die swelling is also greater if extrusion temperature is low. Swelling can be reduced by
reducing the elastic compression. Die L / D relation also helps prevent the die swelling
when the delay time inside the die channel is longer and the stresses have enough time
to release inside the die. Another way to reduce swelling is slower screw speed but this
means also degradation in processing capacity. By ensuring streamline flow,
eliminating dead spots and minimizing pressure drop the die swell will be more
controllable. (Johnson 2001, 107–108, 111–112; Metalliteollisuuden Keskusliitto, MET
2001, 156; Mark & Others 2005, 291; Hahtola 2006, 21, 36; Kothandaraman 2008, 14;
Laurila 2011, 148–150.)
Thermal homogeneity of the compound entering the die becomes more important as the
profile shape gets more complicated. Die swell cannot be eliminated but it has to be as
controlled as possible. If swelling is not evenly distributed in profile the reason is
uneven shear rates in the cutoff walls of die. In corners the shear rate is smaller than in
the middle of the cutoff wall. This leads into greater rate of recovery in the middle of
the cutoff wall than on the edges. In profile this is seen as a bulge. (Johnson 2001, 107–
108, 111–112; Metalliteollisuuden Keskusliitto, MET 2001, 156; Mark & Others 2005,
291; Hahtola 2006, 21, 36; Kothandaraman 2008, 14; Laurila 2011, 148–150.)
Pressure drop is the other important phenomenon besides die swell with the extrusion
dies. Sudden intake from taper to die can cause extrudate distortion when output rate is
low. Distortion can be also result of velocity differences across the profile at the die
exit. Die designing aims to avoid high pressure drop and too high temperature rise.
44
Pressure inside the rubber just before entering the die has to be demolished completely
in that passage through die and out. Pressure drop consists of entrance losses, die losses
and exit losses. Entrance loss is greater than exit loss and it is depending on extensional
flow. Pressure loss in the die is only dependent of die length. Internal and external
lubricant addition can ease the pressure drop phenomenon. Incompatible material, like
oil in NR, creates wall slippage which leads to a greater entrance pressure drop.
Compatible material, like fatty acid derivates, reduces entrance pressure losses.
(Johnson 2001, 107–108, 111–112; Metalliteollisuuden Keskusliitto, MET 2001, 156;
Mark & Others 2005, 291; Hahtola 2006, 21, 36; Kothandaraman 2008, 14; Laurila
2011, 148–150.)
4.4.1 Die shaping
The design of die depends on the wanted profile and specific compound used. Often die
shaping evolves into handicraft process where experimental extrusion is done with the
prototype die shape. After a vulcanized profile has been examined the needed
corrections are done with detail shaping of the die. Shear rates and local temperatures
have to be taken account, for example, around extrusion head is cooling-water
circulation but the die made from metal is warming up and has not got any cooling
possibilities. The hole-maker pins are located inside the hot compound and can develop
problems when the viscosity of compound and screw speed is high. In figure 14 are
demonstrated some optimum shapes of die. The left side of figure 14 is showing this
demo-die from the compound entering direction, notice the thickness of die. The right
side of figure 14 is showing the same die from the compound exiting direction and the
demo-profile extruded with it, notice the relation between the hole and whole die. This
demo-die has breaker surface plate marked with red and chamfers marked with green.
45
FIGURE 14. Optimum Die Shaping (figure: Pauliina Peltola 2013)
The figure 15 is presenting the details of this same optimum die: the red breaker surface
plate and the green chamfers. Breaker surface plate prevents the powerful free-flow of
compound into the open-space part of this particular profile. Without this breaker
surface plate compound is flowing through from this open-space more easily than
through the smaller space under the hole-maker pin that gives the thin wall shape to the
bottom of the profile. This way out-coming profile will be twisted downwards because
more rubber mass is flowing through the upper part of the die. Green chamfers guides
the compound smoothly into the long die where it has enough time to organize its
molecule chains to be more longitudinal orientated.
FIGURE 15. Optimum Die Shaping Details (figure: Pauliina Peltola 2013)
In figure 16 is demonstrated unsuccessful die shaping when the wanted profile is the
same as in figures 14 & 15. The left side of figure 16 is showing thin die from
46
compound flow direction. Its relation between the hole size of die and the diameter of
die is large. This relation is leading to poorer compound flow. Compound flow is been
stopped to the large wall area that keeps the rubber swirling around in the same place.
The ‘handle’ where the hole-maker pin is attached is much closer to the surface of the
die than in the optimum die presented in figure 14. This makes the change from round
flow into a profile shaped flow too sudden. The right side of figure 16 is showing details
of this poorly shaped die without breaker plate surface or chamfers.
FIGURE 16. Unsuccessful Die Shaping (figure: Pauliina Peltola 2013)
4.5 Challenges in extrusion
The biggest challenge in extrusion is the extrusion itself which means the delicate
nature of this process where everything affects everything. Although there are several
mathematic equations included into extrusion, a lot more than presented in this chapter
4, the extrusion is most of all dependent from the users’ skills and intuition. Best results
are often found with gut feeling.
Feed starvation
Feed starvation reduces the distributive mixing action of the extruder and reduces
viscous heat generation. Starvation of the extruder can be avoided with assuring better
feed, increasing the size of the feed-strip or adding an undercut near the feed throat.
More certain way is to add more power to the feed system. The joints of feed strips
should also be under observation meaning too long joints will have effect to the
steadiness of feed. (Johnson 2001, 94–96, 98–99, 106, 113; Hahtola 2006, 86;
Kothandaraman 2008, 14; Laurila 2011, 143, 152, 156.)
47
Limiting factors
When power is available quality and temperature are limiting factors in cold-feed
extrusion. If neither of these two is not in their limit extruder is not working optimum.
Practically the maximum permissible temperature is the main limitation in extrusion.
Most of the energy goes to the cooling of the process. This is due to the fact that only
way to get heat out of the compound inside extruder is direct contact with the cooled
surface. This is why complicated compound flow patterns are vital in cold-feed
extrusion success. These flow patterns keep the surface contact continuously fresh by
offering new rubber surface to the casing and screw surfaces. This leads into more
efficient and faster heat exchange. Pressure development is lower when the screw is
cooled and this leads also to lower pumping volumes. Due to this, compound has longer
residence time in extruder with distributive mixing. This is resulting into a better
thermal consistency of the compound and it is important aid for extrudate dimension
control. (Johnson 2001, 94–96, 98–99, 106, 113; Hahtola 2006, 86; Kothandaraman
2008, 14; Laurila 2011, 143, 152, 156.)
Moisture and volatile components
Moisture and volatile components in rubber compounds will produce porousness which
is prevented with vacuum extruder. It creates vacuum into the cylinder and the light
components are sucked out before homogenous zone. Vacuum extruder consists of in a
way two extruders, cold-feed and hot-feed, located one behind the other. Vacuum
prevents porosity but the extrusion output is lower and temperature higher when it is
used. (Johnson 2001, 94–96, 98–99, 106, 113; Hahtola 2006, 86; Kothandaraman 2008,
14; Laurila 2011, 143, 152, 156.)
Scorch
Compound rotating together with the screw can lead into partially vulcanization of the
compound and worse profile surface quality. It can be prevented by placing pins to the
cylinder towards the screw. Pins will slow down the circular movement in compound
created by the screw. Pins will also create laminar swirls. The wearing of screw ridges
and casing will eventually increase the delay-time and leakage-flow as presented in
chapter 4.4. (Johnson 2001, 94–96, 98–99, 106, 113; Hahtola 2006, 86; Kothandaraman
2008, 14; Laurila 2011, 143, 152, 156.)
48
Melt fracture and shark skin
Typical challenges in extrusion are melt fracture and shark skin on the surface of
extrudate. Melt fracture is due to the helical distortion and elastic turbulence. Shark skin
means transverse ridges on the surface and they are caused by tearing of the melt. Shark
skin happens on higher extrusion outputs. When viscosity increases and the molecular
weight are broader these two problems will be solved. (Johnson 2001, 94–96, 98–99,
106, 113; Hahtola 2006, 86; Kothandaraman 2008, 14; Laurila 2011, 143, 152, 156.)
Cold flow
Cold flow means that extrudate will collapse from its own weight and it has also poor
green strength. This is due to gravity and the fluidic nature of extrudate before it is
cured. Problem will be solved with increase of molecular weight in order to get some
entanglements. Also branching of the main chain will solve the problem when more
cross-links are created. One way to maintain a better shape of the profile after it exits
the die is the usage of shear head. Shear head heats up the die and the extrudate into its
new shape by pre-vulcanization. After all, excessive process optimizing can weaken the
end-products features or affect in a negative way into the profitability of compound
manufacturing. (Johnson 2001, 94–96, 98–99, 106, 113; Hahtola 2006, 86;
Kothandaraman 2008, 14; Laurila 2011, 143, 152, 156.)
49
5 RUBBER TESTING
Rubber testing is a wide area and it is dealt in this chapter only on general level,
concentrating to those features and tests methods which are used in hatch cover seal
production of this certain packing product. Rubber testing can be divided into two areas;
before and after the vulcanization. There are several different features that can be tested:
mass, density, dimensions, short term stress / strain properties, dynamic stress and strain
properties, tack, creep, relaxation, set (permanent deformation), friction, wear, fatigue,
electrical tests, thermal properties, effect of temperature, environmental resistance,
permeability, adhesion, corrosion, staining. Only few of these are used with each rubber
product. Depending on what kind of rubber application it is and what are the most
important features of it that are affecting on its quality as a product. (Brown 2006 index,
31.)
What comes to rubber testing the same scientific general considerations will be present
as with any other material testing. To get reliable results the test equipment has to be
right, calibrated and in good condition. The used test methods have to be standardized
and the person conducting tests have to be professional. Test conditions likewise the
history of test piece has to be taken into account. The person making decisions based on
the test results has to understand deeply enough what has been tested and why likewise
how to use the results in statistic analyzing. With rubber testing there are international
standards to follow. Standards can also be national or company leveled. The
International Standardization Organization is widely known across the world. Their
standards are named ISO. (Brown 2006 index, 31.)
5.1 Testing before vulcanization
Testing before vulcanization means that the interest is the rubber compound before it
becomes a product. These tests are done to find out what the processability of rubber
compound is like. What is done in compounding or what kind of raw materials are used
in it cannot be corrected in anyway afterwards with rubber machinery. Routine tests of
the rubber compound will save costs because any deviation in quality can be detected
before proceeding into machinery. Tests will also tell if there are any other features that
50
could be corrected before proceeding or which will cause difficulties compared to the
normal machinery of rubber. One important feature is dispersion quality which tells
how well has the compound mixing been done. Are the added substances particles in
big agglomerates or evenly distributed across the board with the elastomer. Dispersion
quality effects to the final products surface roughness.
5.1.1 Rheology
Rheology investigates the viscoelastic flow behavior such as stiffness and fluidity.
When rubber is highly plastic it deforms or flows easily. Plasticity is the inverse of
viscosity. With unfilled rubbers viscosity depends from molecule weight average, chain
flexibility and long chain branching. Viscosity tells how much energy is needed to
process the rubber compound. There are different test equipment to measure the
viscoelasticy of rubber. Extrusion rheometers simulate in micro scale the real extrusion
process: rubber mass is pressed through a small hole. Although, there are extrusion
rheometers, none of those are as popular as Mooney shearing disk viscometer is. With
this viscometer, the right vulcanization process phases and scorch resistance can be
studied to each rubber compound batch. (Mark & Others 2005, 325; Brown 2006, 65,
72, 76, 82–83, 104–105; Kothandaraman 2008, 13, 140; Laurila 2011, 187–188.)
Mooney is a rotation viscometer where viscosity is continuously measured: rotor turns
at a constant rate inside a closed cavity containing the test piece so that a shearing
actions takes place between the flat surfaces of the rotor and the walls of the chamber.
The torque required to the rotation is measured as a function of time and the test piece
consist of two rubber discs (d = 50 mm and thickness 6 mm). Results are in Mooney
units where 8.3 ± 0.02 Nm =100 Mooney units. Viscometer is standardized in ISO 289-
1. Standard for uncompounded rubbers is ISO 1795 and for compounded rubbers ISO
2393. (Mark & Others 2005, 325; Brown 2006, 65, 72, 76, 82–83, 104–105;
Kothandaraman 2008, 13, 140; Laurila 2011, 187–188.)
Mooney is also convenient to finding out the scorch and cure rate. It is often hard to
separate these three different features plasticity, scorch and cure rate. This means that
with Mooney it is possible to find out all of these three at the same time. Cure rate
means the time and temperature what is needed to vulcanize the rubber. It also tells the
51
start time of cure. This is very important information to be used in the rubber
machinery, in which ways it is possible to process the rubber compound to avoid the
scorch. One can also be investigating the best cure way of some rubber compound. In
this kind of study different times and temperatures are tested together with the
vulcanized compound features after some specific cure parameter. (Mark & Others
2005, 325; Brown 2006, 65, 72, 76, 82–83, 104–105; Kothandaraman 2008, 13, 140;
Laurila 2011, 187–188.)
Desirable Mooney depends from the applications. When compound is high loaded with
fillers low raw material viscosity close to 30 Mooney units is wanted. For economical
compounds where the oil loading is high, high Mooney close to 100 is wanted. High
viscosity can be achieved with temporary cross links in branched grades, like in liquid
SBR. These cross links break during mixing providing easy mixing with high viscosity.
Raw adhesion is also one of the measured features of un-vulcanized rubber and it is the
ability of the un-vulcanized rubber to get stuck to itself. (Mark & Others 2005, 325;
Brown 2006, 65, 72, 76, 82–83, 104–105; Kothandaraman 2008, 13, 140; Laurila 2011,
187–188.)
5.2 Testing after the vulcanization
For most tests there are standard methods available that usually requires the test piece to
be rested one day after vulcanization, and to be tested at 23 °C with the air humidity of
70 %. There are also many tests for features to be checked without any standard, like
surface appearance and its roughness.
One important issue and special feature of rubber to consider and measure is
dimensional stability. This means in extruding the die swelling after the extruding when
the rubber is relaxing. Dimensions can also be changed when there is some liquid, like
solvents or oils, absorbed into rubber, this leads also to swelling. Another feature that
has effect to the rubber product is thermal dimensional change. (Brown 2006, 104, 173,
259, 342–343; Kothandaraman 2008, 144; Murtoniemi 2010, 48; Laurila 2011, 189–
198.)
52
Elasticity can be measured, if needed, by dropping a metal object on to the rubber sheet
or with pendulum test machine. In standard ISO R 1767 can be found specific
instructions for this. There are also different electrical tests that can be done with the
rubber products: resistance, resistivity, surface charge, electrical strength, tracking
resistance, power factor and permittivity. None of these are done in the hatch cover seal
testing because there is not any electricity involving in their usage. Electrical tests are
more important in other rubber applications like in automotive industry. Electrical
properties depends on not just the elastomers features but from the different features of
the fillers which compound is consisting of. (Brown 2006, 104, 173, 259, 342–343;
Kothandaraman 2008, 144; Murtoniemi 2010, 48; Laurila 2011, 189–198.)
Radiation effects are necessary to find out if the rubber application is used in a nuclear
power plant, or some other places where some kind of like radiation is present.
Sometimes it is also important to find out features concerning biological attack. These
are more likely to be microbiological but also some animals like rats or insects could be
destroying the rubber products. Then solutions to protect the rubber are vital to find.
(Brown 2006, 104, 173, 259, 342–343; Kothandaraman 2008, 144; Murtoniemi 2010,
48; Laurila 2011, 189–198.)
Short term stress / strain properties are studied in tension, compression and shear tests.
Most common and important of these is the compression test, what comes to the hatch
cover seals. Short term dynamic stress and strain properties: dynamic testing means that
the test piece is under some kind of cycles of movement or forces for a certain time.
This could be, for example, an abrasion test in test bench with 2000 cycles, divided into
8 hour periods per day. Different dynamic testing can be united with specific
temperature. (Brown 2006, 104, 173, 259, 342–343; Kothandaraman 2008, 144;
Murtoniemi 2010, 48; Laurila 2011, 189–198.)
5.2.1 Hardness
One important and commonly tested feature is the hardness of rubber. Difference
between hardness and modulus is that hardness is modulus at very low strain, while
modulus tests are done at higher strains (100 – 300 %). Hardness and modulus can be
altering separately from each other although increase of cross link density will improve
53
them both. Hardness cannot be the only criteria what is been measured because it can be
easily increased with cheap fillers, while the rest of the properties are dramatically
reduced. Hardness is measured with a durometer on the Shore –scale in the hatch cover
seal testing. Shore A –scale is for the soft rubbers, Shore D for more harder rubbers and
ShOO for sponge and cell rubbers. On Shore A –scale the rubber with 20 ShA is very
soft and rubber with 80 ShA is hard as a rock. Durometer is spring based meter but
there is available different equipment for conducting other methods like dead load test
method. One of them is the International Rubber Hardness Degress (IRHD) method that
is described in ISO 48 standard. (Brown 2006, 110, 118, 127, 133–134, 149–150, 159,
161; Kothandaraman 2008, 141; Murtoniemi 2010, 44; Laurila 2011, 189–191.)
5.2.2 Tensile stress
Tensile stress strain testing is very important to those rubber products that are used in
tensile positions or have tensile movement during their usage. Hatch cover seals are
avoiding tensile stress in macro scale because their function as a product is based on
compression. Still there are internal tensile stresses present in the microstructure of the
seal (see chapter 5.2.10). In tensile test stress is aimed to the rubber test piece and the
elongation correlation to the stress is examined. This is very common and widely used
test and there are available standards, for example ISO 37, defining the test equipment,
test pieces and the details of this test method. (Brown 2006, 110, 118, 127, 133–134,
149–150, 159, 161; Kothandaraman 2008, 141; Murtoniemi 2010, 47.)
5.2.3 Compression
Compression is tested with the final product and in the specific compression
environment of the rubber application. Compression stress / strain features are the most
important features, what comes to the hatch cover seals. Compression of hatch cover
packing is measured from the final product test piece the length of 200 mm in the
profile holder which is imitating a rubber channel (see figure 17). This set-up is the
same as it is when the packing is finally installed into the hatch cover. The test piece is
compressed evenly at specific speed two times to get a compression curve which tells to
a practiced eye how the sealing is working in a real situation. In compression test the
54
compression force is coming from above and one also has to take under consideration
the force-free areas on the both ends of the test piece, as demonstrated in figure 18.
When the packing is installed into the rubber channel of hatch cover it does not have
such force-free areas.
FIGURE 17. Compression Test (figure: Pauliina Peltola 2013)
FIGURE 18. Force-free Area in Compression Test (figure: Pauliina Peltola 2013)
Hatch cover seal compression is measured force (N) as a function of compression (mm)
from a test piece the length of 200 mm but the standard compression curves for each
seal product is presented in kN / m. Results are in units N / mm and they are converted
as follows. Test piece compression forces are multiplied with 5 to get the needed force
e
F
f
F
F
F
F
55
for 1 m length of the same rubber profile to have the same compression amount. In
equation 3 is demonstrated this conversion with one example (200 N / mm = 1 kN / m).
(3)
5.2.4 Tear
Tear is also essential feature to find out from rubber products. What comes to the hatch
cover seals, the tear test tells how the rubber is able to withstand the hard conditions of
cargo ship. More specific, how it withstands the loading actions, when there could be
some hits and abrasion from the loading equipment accidentally getting contact with the
hatch cover seal. Tear is roughly depiction as a nature of rubber or ability to resist the
flaw spreading, meaning how the rubber resists the continuous of the tear. Depending
on the application and the location of the tear, small tear is not necessarily harmful but
if it spreads to a bigger one the product is not working properly anymore. There are a
few different ways to conduct the tear test. One way is to make trouser test piece and
pull the other leg to another direction and the other to other direction. In standard ISO
34 this tear testing method is defined more precisely. (Brown 2006, 110, 118, 127, 133–
134, 149–150, 159, 161; Kothandaraman 2008, 141; Murtoniemi 2010, 47.)
5.2.5 Creep, relaxation and set
Creep, relaxation and set are based on result of an applied stress or strain together with
time. In creep test the rubber test piece is under a constant force and its deformation
during this time is recorded. Set test investigates how the rubber test piece can recover
when it is released from the stress or strain. There are physical and chemical reasons
that influent on these three phenomena. The first is due to the viscoelasticity of rubbers
and the second arose from the rubbers ageing. (Metalliteollisuuden Keskusliitto, MET
2001, 144; Brown 2006, 201–202, 204, 211, 213.)
The relaxation and set are more essential test features, than creep, what comes to the
hatch cover seals. Relaxation under compression is very unwanted feature with seals if
56
the relaxation is big enough the seal is not working anymore. Relaxation tolerances are
dependent of the seal product end-use environment and requirements. Hatch cover seals
are medium-sized rubber products to be used in very rough conditions and they are
weathertight. Weathertight hatch cover keeps the hold dry when 1 m water statue, called
wave load, is placed on top of the hatch cover. Weathertightness means that no water
can enter into cargo hold through the packing arrangement while watertightness means
that no water can enter or exit the hold through the packing arrangement (Taylor 2001,
41).
Set test can be carried out in tension or in compression, depending of the rubber product
final usage. Set in compression is very important feature to be examined with the hatch
cover seal products. Although the mass of the hatch cover is adjusted to be on the
bearing pads and not on the seal, the seal also has a quite rough compression force over
it. And addition to this, there is the forces due to the swell of the sea. If the maintenance
of a vessel is not up to date, the seal has to carry more weight as it should. Hatch cover
seals spend the most of their life being compressed and only a while without the
compression during the loadings and un-loadings. Compression set test tells the force
limit which the seal can recover from and in what point, it cannot recover anymore from
the compression.
Usually compression set with rubbers is not noteworthy inside the temperature range
from 0 °C to 80 °C. Set test is commonly done as follows; rubber piece is compressed in
the room temperature and then moved into the testing temperature for 24 hours. After
that the compression is moved and test piece can rest 30 minutes before measuring if
there is any set. More information about this method can be found in standard ISO 815.
(Metalliteollisuuden Keskusliitto, MET 2001, 144; Brown 2006, 201–202, 204, 211,
213.)
5.2.6 Friction and wear
There are three types of wearing phenomena: grinding wear abrasion, sticking wear
adhesion and degrading wear due to the oxidation, heat and chemical wear. Friction is
part of the abrasion phenomenon of rubber products. Abrasive wearing is the result of
two phenomena: oxidative decay due to the heat formation from friction and mechano-
57
chemical breakdown started by shear-induced fracture of chemical bonds.
(Metalliteollisuuden Keskusliitto, MET 2001, 140; Mark & Others 2005, 492; Brown
2006, 219, 227.)
Hatch cover seals are compressed against to a steel surface of the coaming or against to
a compression bar made of steel. Seals have to be very tenacious to be able to resist the
rough conditions of the end-use environment. The wear of packing is measured in a test
bench (see figure 19) and it can be lubricated with seawater or some covering on the top
of the seal to ease the friction force to be smaller. With hatch cover seals, the seal with
covering is more difficult application than with some other more gently used seal
products, like the car window seals manufactured by automotive industry. Hatch cover
seals undergo such rough movements that the covering is easily worn out.
FIGURE 19. Sliding Test with Sliding Type of Hatch Cover Packing (figure: Pauliina
Peltola 2012)
5.2.7 Fatigue
With fatigue is meant all those deformations which are due to the long term dynamic
tests. When rubber is under continuing dynamic movement of some kind there will be in
some point, effects to its hardness and mechanical properties. This fatigue can be due to
a thermal breakdown, ozone or oxidation attacks, not forgetting the rubber physically
been torn out. For example, with a seal product fatigue test can be one, where seal is
compressed and released continuously over and over again. After some specific period
the test is stopped and the seal is overall examined, to find out is there any fatigue
happened. There are several different ways to conduct these fatigue tests depending on
the rubber product. In some case it can be necessary to find out how the presence of
mineral oil, for example, will affect to a long term static compression test. Overall,
58
fatigue test can be the ones which imitate the end-use environment. (Metalliteollisuuden
Keskusliitto, MET 2001, 146; Brown, 2006, 245.)
5.2.8 Effect of temperature
Effect of temperature is very important area with the hatch cover packing because they
have to withstand variable weather conditions, depending on where the vessel is sailing.
Most extreme weathers can be -40 °C, or even -50 °C, when the vessel is an arctic
research vessel to be used near the naval areas. There are special hatch cover seals for
this purpose, although the normal cargo vessels also need quite good temperature
resistant packing especially if they sail on some colder passages.
Temperature effect test include both high and low temperatures. Low temperature
effects can be measured with the rate of recovery, change in stiffness and brittleness
point measurement. One of the recovery tests is temperature-retraction test (TR test)
which is standardized with ISO 2921. In TR test a rubber test specimen is in strained
position of 50 % in holder which is put into -70 °C where it is kept for 10 minutes. After
this, it is released from the holder and warmed-up 1 °C / minute. This way, the
temperature where 10 % of the strain is recovered is the TR10 and so on. Brittleness
point is the temperature where the rubber becomes a fragile and glassy. (Mark & Others
2005, 190; Brown 2006, 287, 291; Kothandaraman 2008, 3, 5, 144; Laurila 2011, 194.)
The glass temperature Tg presents cooling rate function at the pressure where it is
determined. Tg depends from chain stiffness, interchain attractions, molecular
symmetry, copolymerization and its types. Also presence of solvents or plasticizers,
branching and cross-linking have got influence to Tg. Above this temperature rubber is
soft and flexible and under it rubber is hard and brittle. Plasticizers and solvents will go
between elastomer chains and this will cause decease of the Tg. In figure 20 is presented
Tg and damping features of natural rubber (adapted from Laurila 2011, 28, modified). In
glass transition region the internal damping of natural rubber is at its maximum. Best
choice to lower operating temperatures is the rubbers with the lowest Tg. In table 3 is
shown Tg values for few elastomers. (Mark & Others 2005, 190; Brown 2006, 287, 291;
Kothandaraman 2008, 3, 5, 144; Laurila 2011, 194.)
59
FIGURE 20. Natural Rubber Tg (adapted from Laurila 2011, 28, modified)
TABLE 3. Tg Values for Few Elastomers (Gent, 2001, 13–17)
Elastomer Tg
SBR -55 °C
NR -70 °C
BR -100 °C
CR -50 °C
IIR -70 °C
EPDM -60 °C
Q -127 °C
The elasticity of elastomers is depending on temperature. Elastomers have very long
non-symmetric molecule chains which can rotate freely. When polymer is crystallized
its molecule chains are packed together symmetrically but elastomer chains are left non-
symmetric. Un-vulcanized rubber can crystallize even in + 10 °C but this is reversible
phenomenon. (Mark & Others 2005, 190; Brown 2006, 287, 291; Kothandaraman 2008,
3, 5, 144; Laurila 2011, 194.)
60
5.2.9 Fire-resistance
The fire-resistance of rubbers has not been under general concern as much as plastics.
Most rubbers burn and burning features can be divided into different aspects like ease of
ignition, rate of burning and smoke production, to mention a few. Synthetic rubbers are
mostly oil-based products and when the rubber burns it is like solid oil is burning. There
are not any ISO standards for the fire test of solid rubbers. (Brown 2006, 343–344.)
Generally the ignition of rubbers is more difficult than with other materials in the
burning environment where rubbers are commonly the ones to start burning last. That
does not mean they are fire safe, it is the opposite, when rubbers burn they are hard to
extinguish and most of them will produce a lot of harmful or even toxic smoke during
their burning. There are fire-resistant rubber compounds that can be used in hatch cover
seals. More often customer wants non-fire-resistant rubber compounds which are more
inexpensive ones. When the other marine seal products are used in a vessel where there
are passengers or roll-on-roll-off cargo it is more important to have also the seals fire-
resistant. This is because the seals are located inside the vessel in the compartment
doors and ramps. (Brown 2006, 343–344.)
5.2.10 Ozone
Ozone (O3) is more aggressive natural form of oxygen gas (O2) in the nature and it is
mostly present in the higher atmosphere. Ozone level varies around the world. It is more
usual to conduct only ozone test that measures the ozone resistance between different
rubber compounds than test the rubber in end-use environment ozone levels. Rubbers
are very delicate to ozone and even 1 part per hundred million (pphm) can cause
cracking in rubbers if they are in strained situation. Cracks will happen always
perpendicularly against the strain direction when ozone cuts the double bonds (C=C) of
the rubber. When rubbers are used in applications where there are tensile strains focused
on it, the ozone resistance is very important to cover. Hatch cover seals are in
compression but there are still tensile strains present in the microstructure of seals (see
figure 21). Because of this, it is also very important to measure ozone resistance, due to
the absorption and diffusion of the rubber material. Usually the ozone levels in the tests
are in the range from 25 pphm to 200 pphm, 50 ± 5 pphm being the general standard
61
level. (Metalliteollisuuden Keskusliitto, MET 2001, 150; Brown 2006, 327–329, 331,
333.)
FIGURE 21. Local Tensile Stress in Microstructure of a Hatch Cover Seal (figure:
Pauliina Peltola 2013)
Ozone testing is quite complicated because there are also two other factors present: time
and the amount of strain, besides of the ozone concentration. These three together will
make different variable situations and the ozone cracking factor is quite hard to define.
Even if the rubber compound has very good resistance to ozone its threshold level in the
strained position can be very low. Normally the ozone tests are accelerated tests and
done in special ozone cabinets where the material of cabinet is chosen to be undecayed
one to ozone. One important thing to consider in closed ozone cabinet is that the rubber
test piece itself can give off gases which can have effect to the results. If test piece has
some minimalistic flaws or patterns they will act as stress raisers and encourages the
cracking during the test. In standard ISO 1431 the test method is described in more
details. (Metalliteollisuuden Keskusliitto, MET 2001, 150; Brown 2006, 327–329, 331,
333.)
5.2.11 Environmental resistance
Rubber products are often exposed to a combination of different chemical and physical
features at the same time. This is why it is more practical to conduct test which will
simulate the working conditions of the rubber than just test the rubber separately with
these different features.
62
Moist heat testing will tell more efficiently the features of rubber product in real end-use
environment than dry heat testing. This kind of product which needs moist heat testing
can be a steam hose or some other rubber product which is in contact with steam. The
effect of different liquids also is very important thing to test. Liquid effect is commonly
tested with the volume change of the rubber when it is in contact with liquids. There can
be different liquids in contact with the rubber product even though not directly supposed
to. Regarding hatch cover seals, the most contact it has is with the sea water which has
the salt content of 3.0 – 3.8 % NaCl. The seal will be in contact with other liquids too,
although it would be a bulk vessel, carrying dry cargo. For example, there is always
sulfur present in the coal bulk and when it comes in contact with sea or rain water,
sulfur acid is formed (see chapter 6.3). (Brown 2006, 317, 319, 326, 339–341, 349–
350.)
There are also other gases besides ozone which are sometimes needed to test with the
rubber products. Hatch cover seals are usually only tested for the ozone resistant but
there are some seal applications where other gases are present. It is necessary to find out
the permeation of the different gases threw the rubber with those applications. In this
kind of situation seal can be working properly stopping the liquid but not the vapor.
Difficulties will arise, when it is necessary to find out permeation in very high
pressures. The test conditions and equipment have to be very safe. Most likely the
equipment has to be made uniquely for only testing this certain application. (Brown
2006, 317, 319, 326, 339–341, 349–350.)
Depending of the vapor or gas and the rubber compound, it could be said that every
rubber is permeable in some scale. Whether this is a problem or not is a consequence of
the applications where the rubber product is used. When rubber is used in some water
vapor barrier or in some gas sealant system it is obvious that no permeability is aloud.
Even mechanically flawless rubber product will let threw some gases or vapors threw
the absorption and diffusion. (Brown 2006, 317, 319, 326, 339–341, 349–350.)
Weathering means combination of several different factors at the same time in contact
with the rubber product. It is very different to test ozone resistance and temperature
features separately than at the same time. Testing them separately could give too
optimistic test results leading than when the testing is weathering type. These tests
63
could be divided into real outdoor tests and into the artificial ones that are simulation
tests in laboratories. Weathering could be roughly said as a test where ozone, oxygen,
temperature, moisture and sunlight are affecting the rubber. These are the natural factors
in outdoors but in some cases it would be more truthful to test the rubber product in the
conditions it will be used. For example, if there are any other factors included, like
crude oil or solvents. These kind of special factors in the rubber products end-use
environment could turn the normal weathering test results to its opposite. (Brown 2006,
317, 319, 326, 339–341, 349–350.)
When the temperature is normal oxygen will effect very slowly to the rubbers. Sunlight
has not been as concerning issue with the rubber, than with the plastic products. Rubber
is most likely to be affected from sunlight only by its surface, although, the exception
are non-black rubbers. All hatch cover seals are black and their permanent position is
quite effectively hidden from sunlight inside the hatch cover steel construction. The
same thing, as with the ozone, is seen with direct UV-light. When the rubber is stressed
or has some flaw the cracking is more likely to happen. Even if the ozone level is low
UV-light will cause cracking. It has been studied and confirmed that the effect of UV-
light can be quite large although rubber compound includes carbon black. In same study
ozone effects were demonstrated to be also significant. Ozone resistant should be first
considered before conducting any thermal ageing tests, when one is trying to find out
the expectable service life. New hatch cover packing products are always tested in the
final stage on-board at least a year and the results are carefully studied before releasing
the new product into the markets. There is ISO standard available for exposure to a
maritime environment but it is only for plastics. (Brown, Butler & Hawley 2001b, 12;
Brown 2006, 317, 319, 326, 339–341, 349–350.)
64
6 CARGOSHIPS AND HATCH COVER PACKING
There are several cargo ship type classes and these classes are divided further into sub-
categories based on size or cargo type, for example. There are also available different
types of hatch cover depending on the specific technical application needed for the
vessel. This chapter is accentuating only into bulk carriers and one type of hatch cover
because this final thesis is studying the extrusion of packing product used only in side-
rolling hatch covers.
6.1 Cargo ship types
All cargo ships can be roughly divided into bulk carriers, container vessels, general
cargo ships, roll-on-roll-off (Ro-Ro) vessels and tankers. Bulk carriers are clarified
better in the chapter 6.1.1. Picture 3 (adapted from Cargotec 2013) is showing different
types of vessels, starting from left, container vessel, general vessel and Ro-Ro vessel.
PICTURE 3. Container, General and Ro-Ro Vessel (adapted from Cargotec 2013)
Container vessels are specialized to transferring containers and there is no other cargo
besides of them. General cargo ships are more flexible with their cargo possibilities than
other vessel types. They can take on-board containers, bulk cargo and different kind of
general cargo, for example, machines or paper baggy reels. General cargo vessels can
also have their own cranes on-board. Ro-Ro vessels are carrying cargo which is on-
wheels, like trucks and cars. Tankers are bulk carriers but they are separated into their
own class because the cargo is in unpacked liquid form and in bulk carriers the cargo is
in unpacked solid form.
65
6.1.1 Bulk carriers
Bulk carriers are cargo vessels that carry solid unpacked cargo. In picture 4 (adapted
from Cargotec, 2013) is seen a bulk vessel. Bulk carriers can have, for example, grain,
ores, coal, minerals or products of chemical industry (like fertilizer) in their holds. In
new building the planned general cargo manifest sets demands for the vessel structure.
Main thing to consider is the movement of bulk cargo in the holds, the slipperiness of
bulk and rolling tendency which sets demands to the stability of vessel. Moving bulk
cargo in the holds makes dynamic moments which try to careen the vessel. Bulk carrier
sizes are classified often by the sea-lanes they are taking or ports they are visiting, some
examples are shown in table 4.
PICTURE 4. Bulk Carrier (adapted from Cargotec, 2013)
66
TABLE 4. Bulk Carrier Types (Räisänen 1997, 24-1–24-16; Bimco 2011)
Bulk carrier Explanation
Weight in dead weight tons
(means everything on board
and the vessel itself)
Small Specific vessels, build for
some special purpose (most of
these are general cargo ships)
-25,000
Handy-sized
(usually with 5 cargo holds)
Convenient bulk vessels,
because they can access to
almost every bulk harbor with
the 11 m draught
25,000 – 45,000
Panamax-sized
(usually with 7 cargo holds)
Max. width 32.20 m (because
of the narrowness of Panama
canal)
60,000 – 99,000
Cape-sized
(usually with 9 or more cargo
holds)
The biggest bulk carriers,
which are determined to take
the routes from the South
when moving past Africa or
South-America, due their size,
no canal is big enough
100,000 – 199,000
Very large ore carriers,
VLOC
(usually with 7 cargo holds)
Gigantic vessels for iron ore,
build to reduce the cost per
tonne mile of cargo +200,000
Most important specification to the bulk carrier is the stowing factor of bulk cargo. The
specific gravity of iron ore is very high. This is why the hold departments are small and
extra strong build in ore carrier. Another specific feature with bulk carriers is dust
which spreads onto the surroundings when the cargo is loaded into the vessel or
unloaded from the vessel. Coal cargos also have different risks on the bulk carriers like
the occurrence of methane, which can lead to explosions and the spontaneous
combustion of the coal if the hold temperature rises too much. (Räisänen 1997, 24-1–
24-16.)
Bulk cargo is quite vulnerable depending on which type of cargo is been carried. Un-
packed cargo can have specific demands concerning the wetting tolerance, air saltiness
defects, caking and swelling, freezing, ageing and many more. Bulk cargo handling will
most probably be more restricted what comes to loading and un-loading, in future.
Environmentally concerns will push the load-handling into closed structures which will
lead into a cleaner way for the surroundings to load and un-load the holds. Closed load-
handling structure is actually a better way for the vessels components also when the
bulk is not spread all over them. (Räisänen 1997, 24-1–24-16.)
67
6.2 Hatch covers and hatch cover packing
The main task for hatch covers is to protect the cargo inside cargo holds and carry
cargo, like containers or special cargo, on top of them. This may seem like a simple task
but actually it is surprisingly complex one. Hatch covers which are shielding the cargo
in the holds are weatherproof although container vessels can have exception into that.
Different hatch cover types are available depending on their needed function and the
vessel they are designed to. One demand for hatch covers can be the ability to get them
out of the way, into a very tight package when the hold is operated. In this case the
hatch cover type could be folding hatch cover.
Hatch cover usage regardless of vessel type should be reliable, easy and fast. These
guarantee short port time and undamaged cargo. There are available different kinds of
hatch cover types: folding, lift-away and side-rolling. First two are seen in picture 5
(adapted from Cargotec 2013, modified).
PICTURE 5. Folding and Lift-away Hatch Covers (adapted from Cargotec 2013,
modified)
Hatch cover packing was made of sponge rubber for a long time until sponge rubber
was harder and harder to get. To solve this unfilled demand extruded hatch cover seals
were invented and step-by-step more profile designs were created hand-in-hand with the
current need from the operating field.
The hatch cover seals provided by the company have got unique geometry and
functionality likewise high quality reaps the benefit compared to the competitors.
Competition on the global markets is very hard and brutal. Manufacturers will make
68
copies from the most famous packing products around the globe and sell them using the
same brand name as a general standard or description of the seal type.
When the hatch cover with its packing and other components is installed into the vessel
its weathertightness is tested. Most common one is the hose test which is proved by
many classification societies to be accurate enough when it is done with the particular
standard features. Hose test is generally done as follows; water with the pressure of 2 –
3 bar is sprayed with a hose inside diameter of 20 – 30 mm from a nozzle with diameter
12 mm from a distance range of 1 – 1.5 m moving along the seal joint 1 m with every 2
seconds. Another test for the weathertightness is ultrasonic test. In this test ultrasonic
generator is placed inside the cargo hold. After closing the hatch cover professional
operator can interpret the readings from several sensors that are placed all around the
compression joints. (Taylor 2001, 43; 44.)
Hatch cover tightening arrangement need different kind of packing pieces, like basic
linear rubber, flat corners, standing corners, 3-way corners and end pieces. What comes
to the hatch cover corners they can also be something else than 90° corners. This leads
also to vary magnitudes of angle in packing corners.
Hatch cover seals can be conventional or sliding ones. Conventional ones are inside the
rubber channel and they are pressed against a compression bar which is mounted onto
the coaming, see figure 22 right side. Sliding ones have bigger movements and they are
pressed against coaming, see figure 22 left side. When sliding seal is used the friction
between coaming and rubber should be appropriate size. Too large friction will wear off
the packing surface too quickly. Although too small friction can reduce the seal feature.
Wear abrasion test is very important for the hatch cover seal because it has to undergo
rough forces and movements during the swell of the sea. Rubber is designed to stay
inside the rubber channel, due to the tight fitting and glue is used to achieve
weathertigthness. Usually hatch cover packing is changed after 5 to 10 years or when
they have damaged someway because of some special event.
69
FIGURE 22. Sliding Seal Type and Conventional Seal Type Arrangements (figure:
Pauliina Peltola 2012)
6.2.1 Side-rolling hatch covers and the new packing product
Side-rolling hatch covers are used in bulk carriers and they only have wave load but no
payload on them. This hatch cover type is made with open steel structure. There are
usually 4–8 pairs of panels, opening from the middle as seen in picture 6. Side-rolling
hatch cover can also have only one panel which is opening onto the other side of the
vessel (see picture 7).
PICTURE 6. Side-rolling Hatch Cover with 2-Panels (adapted from SMBA 2010)
70
PICTURE 7. Side-Rolling Hatch Covers with 1-Panel (Macor Marine N.D.)
In figure 23 (adapted from Cargotec 2013, modified) is shown side-rolling hatch cover.
In figure 24 is shown tightening arrangement of side-rolling hatch cover with 1-panel.
These arrangements can evolve quite complex when steel structure of hatch cover
consists of many different shapes that leads to complex 3-way seal joints.
FIGURE 23. Side-rolling Hatch Cover with 1-Panel (adapted 2013 from Cargotec. Side-
rolling hatch cover drawings, modified)
FIGURE 24. Tightening Arrangement of Side-rolling Hatch Cover with 1-Panel
(adapted 2013 from Cargotec, modified)
71
Typical feature with openings of bulk carriers are their small size with relation to the
cargo holds sizes. Bulk vessels have the biggest seal volumes compared to other vessel
types. Into one bulk carrier is required few hundred meters of hatch cover seals.
Commonly these hatch covers sizes are from 14 to 21 m. This leads to smaller
movements of the opening during the swell of the sea. Bulk carriers are swimming
deeper than the other vessel types. Hatch covers are calculated weatherproof with 1 m
seawater on top of them. This means large weight on top of the hatch covers and large
water pressure to the hatch cover seals. Packing arrangements can be solved with the
conventional packing and compression bar (see figure 25) when the movements of
openings and hatch covers are small.
FIGURE 25. Conventional Seal Arrangement (figure: Pauliina Peltola 2012)
When a new product is coming to the markets it has to have a good reason for the
customer to choose it. More often, the new product is better but also more expensive
than the older version. This makes it a big step to take for the customer to change the
reasoning to the new product version. The linear hatch cover packing product studied in
this final thesis is seen in figure 26. It is easier to install into the rubber channel because
it is lighter than its predecessor. Still this new version has the same compression
capacity leading it to be a more sophisticated packing product.
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FIGURE 26. 3-holed Flexseal, Wingseal (adapted from Cargotec 2013, modified)
6.3 Operating conditions and demands for the hatch cover packing
The need of weathertight holds is the reason why seals are originally invented and used
in hatch covers. Weathertightness is the first feature which is a basic demand for the
hatch covers, including rubber application. This rubber application also has to be
durable under rough conditions and have resistance to wide temperature range and
possibly to wide chemical range. Operating temperature onboard can vary from - 40 °C
to + 50 °C, although certain vessels are for specific sea-lanes and purposes, for example,
arctic vessels are built for cold-conditions and the hatch cover packing is arctic quality.
Another easy thing to consider in the end-use environment is the salty seawater which
does not cause as big problem to rubber as it does to the metal structures and
components of a vessel. Steel components are rusting and it is very fast in sea-
environment although the steel structures are treated with different protection layers.
Cargo vessels are in a heavy usage and in a new vessel there soon will be scratches
breaking the protection layer leading to rusting.
Ozone is present in everywhere on Earth and some special situation, like strong UV-
radiation, can lead into increase of the temporary ozone levels. Another new aspect to
consider in ozone testing of hatch cover seals is ballistic-water treatments with ozone.
This causes high ozone levels to the air statue on the top of the ballistic-water surface
and the hatch cover seal is exposed to this air statue.
Other chemical features could easily be left out from the wanted feature list of the hatch
cover seal. These are the ones which unlike cargo or other features in vessel or at the
73
ports will cause. For example, coal cargo demands a lot from the materials in the hold.
Coal contains sulfur compounds which in contact with water forms sulfuric acid
(H2SO4). Another typical problem in the cargo holds is iron sulfate (FeSO4) with its
crystal waters. It frees very sour oxidative crystal liquid to the steel floor structure. If
matters like these are taken under consideration when the new vessel is being under
delivery or before the service has chosen the new spare seals to replace the old ones it
will have positive effect to the service-life of packing. Most reclamation about hatch
cover packing is due to some other factor than seal itself. Sometimes, if reclamation is
done because the seals are decomposing in some way the reason could be harder to find
out. In this situation the correct type of seal is manufactured and installed properly there
still can be present some specific chemical feature onboard that is causing the problem.
(Räisänen 1997, 24.1 – 24.16.)
In vessel during sea-voyage there are dynamic and static forces present (see figure 27)
that are effecting to the tightening arrangement of hatch covers. Dynamic powers are
due to the ship movements and static powers come from the normal usage of the seal
which is under compression force. During the sea-voyage swell of the sea will cause
multiple dynamic powers into the vessel and its components, like hatch covers. The
hogging and sagging will twist the hold opening and packing along with it (see figure
28). (Räisänen 1997, 24.1 – 24.16.)
FIGURE 27. Ship Movements (adapted from Räisänen 1997, 24-1 – 24-16, modified)
74
FIGURE 28. Hogging and Sagging (adapted from Global Security N.D.)
Hatch cover seal does not take the hatch cover weight on itself because the weight is
guided on to the bearing pads. One hatch cover steel panel can have a weight of 30 tons
and if it has 30 m of seal it leads to situation where 1 m seal portion has 1000 kg weight
on it. Without bearing pads that are supporting the hatch cover weight, the hatch cover
seal could not withstand the weight. It is also important that enough sealing force is
available for the packing. This force is keeping the sealing surface of the rubber and the
corresponding metal surface together. Sealing force is also needed for keeping the joint
tight during the big side-way forces from waves focusing on to the side of the seal.
When the bulk carriers are loaded and unloaded there are always some dust and even
bigger quantities of the cargo spreading on the top of vessel, including rubber seal.
Seals are made into these rough conditions and the compression range covers the small
objects between the seal and steel structures. In maintenance instructions there are
advised one to clean the biggest dirt off from the sealant area before closing the hatch
cover. In picture 8 is seen bulk cargo loading and demonstration of packing with some
dirt particles on it. Even common sense should tell that seal would be working more
properly without any objects from the bulk cargo attached to it.
75
PICTURE 8. Loading and Dirty Packing (adapted from de Souza 2009, modified)
6.3.1 The future of hatch cover packing
It is supposed that the demanding of rubber seals is decreasing because of the
shipbuilding industry is slowing down. This derives from the global economic situation.
Year 2014 is assumed to be better. (Nieminen 2012)
In container ships the coming trend is to build bigger vessels which freeboard height is
increasing so much that they do not need weathertight hatch covers anymore and the
rubber product volume is decreasing on the new-builds. In this vessel category high
freeboard means that no wave is big enough to swept over the vessel and the speed of
the vessel is decreased to 16 knots. Giant container vessels are not watertight from their
holds and they have different kinds of labyrinth structure between the hatch covers to
guide the rainwater into the ocean or pumps to get water away from the holds.
(Nieminen 2012)
Shipbuilding industry and the markets around it are changing all the time. There can be
totally different trends or better innovations coming around the corner that effect to the
rubber packing products, also. (Nieminen 2012)
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7 CONFIDENTAL
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8 CONFIDENTAL
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9 CONFIDENTAL
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10 CONFIDENTAL
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11 CONFIDENTAL
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REFERENCES
Aho, J. 2008. Kumiekstruusion optimointi. Plastics Engineering. Lahti: Lahti
Polytecnic. Final Thesis, Abstract, 33– 34.
ASTM International. 2004. D 1646 – 04 Standard Test Methods for Rubber—Viscosity,
Stress Relaxation, and Pre-Vulcanization Characteristics (Mooney Viscometer).
Standard. ASTM International. USA, 1–12.
Bimco. 1.8.2011. The Very Large Ore Carrier (VLOC). Read 18.02.2013.
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ATTACHEMENTS
Attachement 1. Confidental
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